KR20120017182A - A smart device - Google Patents

Abstract

PURPOSE: A smart device is provided to reduce power consumption and to support reasonable power consumption by automatically controlling power consumption. CONSTITUTION: A control unit(25) is connected to an interface unit(34). The control unit controls the operation of an electronic apparatus(100) based on power expense information and modified power expense information. The control unit controls the electronic apparatus based on a control command by referring to the modified power expense information and forced control command. The modified power expense information is extracted based on the rate of available power in a sub power source.

Description

Smart device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a smart device, and more particularly, to a smart device whose driving state can be forcibly controlled by a command of a power company or an external load control.

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 for electricity was not only available in real time, but only limitedly through the power exchange, and since the price system is also a de facto fixed price system, incentives such as incentives to consumers through price changes cannot be used. There was a problem.

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, in order to realize such a smart grid from the perspective of a power consumer such as a home or a building, it is necessary to bidirectionally communicate with a power supply source and power information, instead of unilaterally receiving power from an individual home appliance and a network to which a plurality of home appliances are connected. And the need for new devices for this two-way communication.

In addition to bidirectional communication for elastic power supply, when power demand is temporarily concentrated, such as in summer, such power demand is dispersed or forcedly lowered to prevent sudden power outage of the power grid. There was also a need to improve stability.

An object of the present invention is to provide a smart device that can be forcibly operated according to a control command provided outside of a power source.

In addition, it is another object to provide a smart device that can determine the actual power demand and power supply in consideration of the amount of power of the auxiliary power source installed in the power demand destination and can be controlled accordingly.

The present invention for achieving the above object, in the smart device for monitoring and controlling the operation of the electrical appliance,

An interface unit for recognizing external electric power charge information and an external forced control command for the electric appliance, and recognizing the amount of available electric power of an auxiliary power source in the home;

Is connected to the interface unit, and controls the operation of the electrical appliance based on the external power rate information and the modified power rate information derived based on the ratio of the available power of the auxiliary power to the power requirements of the home, And a control unit for controlling the electric appliance based on the forced control command in preference to the control command based on the revised power rate information.

The control unit stops the operation control of the electrical appliance based on the modified power rate information when the mandatory control command is input during the operation control of the electrical appliance based on the modified power rate information, and controls the control command of the load control device. It is characterized by controlling the operation of the electrical appliance based on.

The controller determines whether the received external power bill information and the modified power bill information exceed a predetermined reference value,

When the external power bill information and the modified power bill information exceeds a predetermined reference value, the electrical appliance controls to perform the first operation mode,

When the external power bill information exceeds a predetermined reference value, and the corrected power bill information is less than a predetermined reference value, the electric appliance controls to perform a second operation mode in which power consumption is greater than that of the first operation mode. It is done.

The controller may be configured to control the amount of internal power supply of the auxiliary power source to be used when the second operation mode of the electrical appliance is performed.

The first operation mode is characterized in that to limit the performance of at least one of the plurality of power consumption unit or to stop the operation.

In the first operation mode, the power consumption unit has a relatively high power consumption among a plurality of power consumption units, or limits the performance of the power consumption unit that consumes a predetermined reference power or more.

The quantity, power rate, or driving time of the power consumption unit driven in the second operation mode is greater than the quantity, power rate, or driving time of the power consumption unit driven in the first driving mode.

When the second operation mode is performed, the power supplied from the auxiliary power source is supplied to a low power consumption unit whose power consumption is below a predetermined standard.

The correction power bill information calculation is calculated in consideration of the ratio of the power supplied from the system power associated with the external power bill information and the power supplied from the auxiliary power available at a lower price than the external power bill information. do.

The controller may control the power consumption amount of the electrical appliance according to the control command of the load control device to be less than the power consumption amount according to the first operation mode.

The modified power rate information may be calculated by multiplying the power rate information per unit time by the ratio of the required amount of external power to the required amount of power in the home.

The required power amount, the available power amount of the auxiliary power source, and the external power rate information are received or obtained at a predetermined unit of time, and the modified power rate information is calculated at every predetermined unit of time.

The smart device may be provided in the electrical appliance or as a separate component from the electrical appliance.

A modified power rate information calculating unit provided in the electric product or provided as a separate component from the electric product, communicable with the interface unit, and calculating the modified power rate information;

The modified power rate information provided in the electrical product or provided as a separate component from the electrical product, and provided to communicate with the modified power rate information calculating unit and the controller. It characterized in that it further comprises a correction power rate calculation unit for outputting to the control unit.

According to the present invention, in the situation where the power demand is concentrated at once, there is an advantage that can prevent the power outage due to insufficient power supply by forcibly adjusting the power demand.

In addition, it compares the amount of power supplied with the amount of demand, but calculates the user's reasonable power consumption in consideration of the internal power supply that can be supplied by the power source such as a home, office, or factory. Can help.

1 is a schematic diagram of a smart grid.
2 is a schematic diagram of a power management network in which a smart device according to the present invention is provided.
3 is a front view of the energy management device of the smart device according to the present invention.
4 is a control block diagram of a power management network in which a smart device according to the present invention is provided.
5 is a control block diagram illustrating a connection state between an interface unit and a control unit in the smart device according to the present invention.
6 is a control flowchart illustrating a control flow based on power rate information in a smart device according to the present invention.
7 is a control flowchart illustrating a control flow based on a forced control command in a smart device according to the present invention.
8 is a control flowchart illustrating a process of calculating modified power rate information.
9 is a graph showing a change in the external power requirement according to the change of time in the present invention.
FIG. 10 is a graph illustrating external power rate information and modified power rate information according to a change of time in the present invention.
FIG. 11 is a diagram illustrating a step-by-step control situation in a smart device according to power rate information and a forced control command in the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

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

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. The electricity transmitted from the substation is distributed to the office or each household via the power storage device.

Even in homes that use the Home Area Network (HAN), it is possible to supply electricity by producing electricity by itself through fuel cells mounted on solar power or PHEV (Plug-in Hybrid Electric Vehicle). The remaining electricity can also be sold outside.

In addition, smart meters are installed in power demands such as offices, homes, or factories, so that users can grasp the power and electricity rates used at each demand location in real time. Therefore, measures can be taken to reduce power consumption and electricity bills.

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 (EMS), which is responsible for real-time power management and real-time prediction of power demand, and an advanced metering infrastructure (AMI), which measures power consumption in real time, are pivotal. Play the role of person.

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."

In other words, the real-time price signal of the power market is relayed through the energy management device (EMS) and the smart meter installed in each home, and the energy management device (EMS) and the smart meter communicate with each electric product and control the user. By looking at the device (EMS) or the smart meter, the power information of each electric product is recognized and power information processing such as power consumption or electric charge limit setting can be performed on the basis of this, thereby saving energy and cost.

On the other hand, each of the electrical appliances also collects the state information on the operation mode of each electrical appliance, and receives the environmental information such as power information or temperature or humidity received from the energy management device (EMS) or the smart meter and electric It can be reflected in the operation control of the product.

Here, the electronic device capable of operating itself based on the energy management device (EMS) or information provided from the outside by itself may be referred to as a smart device. .

The category of smart devices referred to in the present invention includes the electrical appliance itself, a control device provided inside the electrical appliance, or the energy management device (EMS) or a smart server, and includes all products subject to forced control to be described later. It is desirable to be.

In this case, the energy management device (EMS) communicates information collected by the local energy management device (EMS) by bidirectional communication with a local energy management device (Local EMS) used in an office or a home and the local energy management device (Local EMS). It is preferably composed of a central energy management device (Central EMS) to process.

The smart grid enables real-time communication of power information between suppliers and consumers, enabling "real-time grid response" to be realized, thereby reducing the high cost of meeting peak demand.

2 illustrates a power management network 10 in a home that is a major consumer of a smart grid.

The power management network 10 may receive power information such as power and power rates supplied to each home from the outside, and may measure the power consumption and power rates in the home in real time and the smart meter 20. And an energy management device (EMS) 30 connected to the smart meter 20 and communicating with one or more electrical appliances and controlling their operation.

Here, the energy management device (EMS) 30 includes a screen 31 for displaying a current power consumption state and an external environment (temperature, humidity), and includes an input unit 32 that can be operated by a user. It is preferable to be provided in the form of a terminal.

The energy management device (EMS) 30 is connected to various electrical appliances 100 (101 to 105) such as a refrigerator, a washing machine or a dryer, an air conditioner, a TV, and a cooking appliance through a network inside the home, and bidirectionally with these devices. Communicate.

Communication inside the house can be via wireless or wired, such as a PLC.

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

Each electrical appliance 100; 101 ˜ 105 may be connected to the smart meter 20 or the energy management device 30 and receive and control a control command based on power charge information therefrom.

That is, the subject controlling the electrical appliance 100 is the energy management device 30.

On the other hand, each electric appliance 100 itself is a smart device, and receives the power rate information from the smart meter 20 and the energy management device 30, based on this control based on the power rate information itself You can also perform an operation.

The power supply source 50 for supplying power to the home is equipped with general power generation equipment (firepower, nuclear power, hydropower), or a power company equipped with power generation equipment using renewable energy (solar, wind, geothermal) and the like. It can be a system power source 51.

In addition, the power supply may be a self-generating facility 52 such as a solar power generation facility or a wind power generation facility provided in each home, or a battery 53 provided in a home or a vehicle.

In this case, the battery 53 may receive power from the system power source 51 or the self-generating facility 52 to store electricity, or to store electricity according to the driving of the vehicle.

Here, the self-generating facility 52 or the battery 53 serves as an auxiliary power source different from the system power source 51.

Typically, the power supply 50 is connected to the smart meter 20 and the energy management device 30 to provide them with power and power-related information, and the information provided back to the electrical appliance 100 It is used as the basic information for control in each electrical appliance 100 to move.

However, information provided from the power supply source 50 may be directly transmitted to each of the electrical appliances 100 without passing through the smart meter 20 and the energy management device 30, and through this, the system power supply. In places such as (51), it is also possible to directly provide information for controlling the operation of specific household appliances in each household.

Meanwhile, a load control device 60 forcibly controlling a smart device (electrical product, energy management device, etc.) provided inside the power demand destination is provided outside the power demand destination.

The load control device 60 is typically operated by a power company, and in order to prevent the possibility that a power outage of the entire electric grid may occur because the amount of electric power exceeds the supply amount, each electric power demand connected to the electric grid The control is performed to force the reduction of power consumption in electrical appliances and energy management devices in the.

The load control device 60 is preferably configured in the form of a load control server that can communicate with an electrical appliance or an energy management device (EMS), usually in the power demand, but is not limited thereto.

3 shows a state of an energy management device (EMS) 30, which is a kind of smart device of the present invention.

The touch panel 33 of the energy management device (EMS) 30 is provided with a display unit 39 to display information such as an estimated electricity consumption, an electricity charge, and an estimated charge and carbon dioxide generation amount expected by the accumulated history. And, the real-time energy information and weather information including the time period in which the external power rate and the modified power rate in consideration of the internal power supply amount, the external power rate provided by the utility company in the current time interval is changed.

In addition, it includes a graph showing the power consumption of each time period of each electrical appliance and its change.

In addition, the information on whether the power supply for each product is also displayed in the ON / OFF state.

One side of the display unit 39 is provided with an input unit 38 for allowing the user to set the operation of the electrical appliance, if necessary.

By using the input unit 38, the user can set a limit of the amount of electricity or electricity bill that he or she wants to use, and according to this setting, the energy management device (EMS) 30 can control the operation of each electric appliance. Will be.

On the other hand, in addition to the above-described information, the display unit 39 displays the forced power saving time and the power saving rate according to the forced control when there is a forced control by the load control device (see Fig. 2, 60).

4 is a control block diagram of the present invention.

Here, the system power source 51 is a power supply source supplied from a power company using general power generation equipment (fired power, nuclear power, hydropower).

In addition, the power management network includes a self-generating facility 52 such as a solar or wind power generation facility that may be provided in each home, and a battery 53 such as a fuel cell or a storage cell that may be provided in a fuel cell vehicle or a home. It is included.

The power supply 50 is connected to the smart meter 20 and the energy management device (EMS) 30.

In addition, the smart meter 20 and the energy management device (EMS) 30 are provided to communicate with the electrical appliances.

On the other hand, the load control device 60 is also provided to be communicatively connected to the smart meter 20 or the energy management device (EMS), or connected to each electric product is provided to be communicable.

Therefore, in an emergency situation, that is, in a situation where the power demand in the electric power grid in a predetermined area is close to the power supply amount, the load control device 60 operates to operate the energy management device (EMS) 30 at each power demand. The control may cause the energy management device (EMS) 30 to induce forced power saving operation of each electrical appliance.

Alternatively, each electric appliance in each electric power source may be directly controlled so that power saving operation in each electric appliance is forcibly performed.

In this case, a unique ID is provided for each electric power source or each electric appliance to issue a forced control command for the electric power demand or electric appliance having a specific ID.

Here, the configuration of the energy management device (EMS) 30, the control unit 35 and the input unit 38, the interface unit 34, the display unit 39, and the smart meter 20, The control unit 25, the input unit 28, the interface unit 24, and the display unit 29 are included.

The interface units 34 and 24 are communicatively connected to the interface units 101b, 102b, 103b and 104b provided in the electrical appliance 100 in the home.

The interface unit 34 provided in the energy management device (EMS) 30 or the interface unit 34 of the smart meter 20 receives power charge information and a forced control command from the load control device 60. Function.

In at least one of the energy management device (EMS) 30 and the measurement device (smart meter) 20, the control unit 25, 35 is the setting information input by the user by the input unit 28, 38 And the current accumulated information on the operation of the appliance, power usage history, and the amount of externally supplied power in real time to identify and process.

And, by processing the information in real time to control the operation of the electrical appliances, it is possible to control the power supplied to these electrical appliances.

In addition, the power saving operation of the electrical appliances may be controlled based on an external forced control command received from the interface unit 24 or 34.

The display units 29 and 39 display power information supplied from a power supply source, operation information and power information of an electric product, and matters relating to a communication state of each electric product.

The most important role of the energy management device (EMS) 30 and the measuring device (smart meter) 20 is to provide a power saving mode that can reduce or reduce power bills or power consumption or carbon dioxide emissions during operation of electrical appliances. It is.

In this case, the power saving mode for saving power costs is performed based on information on power rates under variable rates that vary depending on the time that the appliance is operated.

The energy management device (EMS) 30 or the smart meter 20 serves to control electrical appliances in consideration of peak times at which electricity bills are the most expensive during the day, or in consideration of upper limit targets of power consumption or electricity bills. .

Here, the power saving mode operation is preferably performed by subscribing to a power management program provided by the power company.

In addition, it is preferable that such a power management program include forced power saving control to prevent a sudden increase in power demand. Forced power saving control is a load control device provided by a power company irrespective of the user's intention to unilaterally control the power consumption of each customer and the power consumption of each electrical appliance.

If you subscribe to such a power management program and receive power management, you can not only save electricity charges, but also enjoy the beneficial effects such as the electricity rate reduction policy provided by the utility company.

The electrical appliance 100 (101 to 104) includes a control unit (101a, 102a, 103a, 104a), an interface unit (101b, 102b, 103b, 104b), a display unit (101c, 102c, 103c, 104c), an input unit (101d, 102d). 103d and 104d are provided to display the current communication status and to receive a user's command.

In addition, at least one power consumption unit is provided in the electrical appliances 100; 101 to 104, wherein the power consumption unit means a unit that consumes power in each electrical appliance, and in the case of a refrigerator, a compressor or a cold air fan. It will be a motor, and in the case of a washing machine, it will be a rotating drum motor or a drying heater.

In other words, each power consumption unit is a component that consumes power while helping each electrical appliance perform its own function.

In the present embodiment, although the power consumption unit is composed of the first power consumption unit (101e, 102e, 103e, 104e) and the second power consumption unit (101f, 102f, 103f, 104f) in each electric product, power consumption The quantity of units can vary.

The interface units 101b, 102b, 103b, and 104b provided in the electrical appliances may receive real-time power information from the energy management device (EMS) or the smart meter 20, and the load control device 60 It can also receive the forced control command sent from.

The interface unit 101b, 102b, 103b, 104b is communicatively connected to the energy management device (EMS) 30 or the smart meter 20 so that the command according to the power management program issued through the control unit is controlled. 101a, 102a, 103a, 104a to be performed in the electrical appliance 100.

On the other hand, the current time is the peak time interval by using the power information received from the energy management device (EMS) 30 or the measuring device 20 for each electric appliance installed with the control unit (101a, 102a, 103a, 104a) It can determine power saving operation or forced power saving operation by itself.

Here, the power saving operation may be performed not only in one operation mode but also in various power saving operations in consideration of savings such as power consumption or electric charge.

Fig. 5 shows a specific internal control block diagram of the energy management device 30, which is one of the smart devices of this embodiment.

The interface unit 34 may be classified into various parts. First, a power rate receiving unit 34a capable of receiving external power price information (EP), an auxiliary power source provided in the power requester, That is, the internal power supply detection unit 34b capable of detecting an internal power supply (IS) that can be supplied inside the power demand, such as the amount of self-generation in the power generation facility or the amount of power storage in the battery, and each electric power. And a required amount obtaining unit 34c capable of obtaining data related to a total demand (TD) required by the product.

The power requirement amount TD may be a power consumption amount of an electric product used at present time, or may be a predicted value of future power consumption based on a power usage history of each electric product.

Data on power usage history for each appliance includes power consumption data for each appliance type, function, and season, which may be data provided by the manufacturer as well as data accumulated at the point of demand.

On the other hand, in the case of the internal power supply (IS), when there are a plurality of self-generating device, it includes the total amount of power generated by each power generating device.

For example, the sum of the amount of power generated by the photovoltaic device, the amount of power generated by the wind power generator, and the amount of storage of the battery may correspond to the internal power supply (IS).

 If the internal power supply (IS) is also a measured value corresponding to the current time, it may correspond to a value detected from the home generator, and if it is a predicted value corresponding to a future time, the estimation is based on data of power generation of each generator. It may be a value.

Data on power generation of each power generation device is data for predicting power generation amount according to generator type, date, season, time zone, etc., and may correspond to historical power generation generation data, or data about natural environment (sunlight, Wind speed, etc.) In the case of a battery, data may be included in the charge / discharge capacity and the like.

The external power fee information EP, the internal power supply amount IS, and the power required amount TD are transmitted to the modified power rate calculator 36 to calculate a corrected price CP. Used as

The modified power rate refers to a power rate actually paid by the consumer in consideration of the amount of power supplied from an external system power supply and the amount of internal supply power supplied from the inside.

The modified power rate CP calculated by the modified power rate calculator 36 is output from the modified power rate output unit 37 and moved to the controller 35 to control the operation of the electrical appliance. Used as

Hereinafter, a calculation of a modified power rate (CP), power consumption control, and forced power saving control will be described.

As shown in FIG. 6, when the electrical appliance operates (S601), first, the smart device recognizes external power rate information EP (S602).

In addition, the internal power supply amount IS of the indoor auxiliary power source is recognized (S603), and a modified power rate based on the internal power supply amount IS, the external power rate information EP, and the power required amount TD ( CP) is calculated (S604).

Here, the process (S604) of calculating the modified power rate information CP will be described in detail with reference to the flowchart of FIG. 8 and the graphs of FIGS. 9 and 10.

As shown in Figs. 8 and 9, the required amount obtaining unit (see Fig. 5, 34c) preferentially obtains the power required amount TD (S801), and the internal power supply detecting unit (see Fig. 5, 34b) An internal power supply amount, such as the amount of power generated by the self-generating facility or the amount of storage of the battery, is detected or predicted (S802).

In addition, the power rate receiving unit 34 (see FIG. 5) receives external power rate information EP (S803).

The external power bill information (EP) may be received by a method such as power line communication (PLC), Internet Protocol (IP), etc., but the present invention is not limited to a specific method.

On the other hand, the power demand (TD) is to be covered by the external power demand (ED: External Demand) that needs to be supplied from the outside (for example, grid power) and the amount of power supplied from the inside (for example, self-generation facilities, batteries). The external power requirement ED is calculated by subtracting the internal power supply IS from the power requirement TD (S804).

That is, the external power required amount ED is calculated through the following equation.

The external power requirement ED is represented by a difference between the power requirement TD indicated by a dotted line and the internal power supply IS indicated by a solid line in FIG. 9, and the power requirement TD and the internal power supply amount ( If IS) changes over time, the external power requirement ED also changes over time.

In the graph of FIG. 9, in the section where time t is from 0 to t ₁ and the section after t ₂ , the internal power supply IS is less than the power requirement TD, and the time between t ₁ and t ₂ In the section, the internal power supply amount IS exceeds the power requirement amount TD.

For example, a section between t ₁ and t ₂ may correspond to a section having a large amount of sunshine or high wind speed.

That is, in the interval between t1 and t2, since the internal power supply amount IS is greater than the power demand amount TD, the external power supply amount ED has a value of zero. In this case, since there is an internal surplus power amount, the surplus power amount can be sold to an external power exchange or a power company.

If the internal power supply amount IS is less than the power requirement amount TD, and the externally supplied power is to be used, it is determined that the external power supply amount ED is equal to or greater than zero (S805), and the internal power supply amount IS And the modified power rate information CP is calculated based on the required amount of external power ED.

Calculation of the modified power rate information CP by the modified power rate calculation unit 36 is performed by dividing the external power requirement ED by the power requirement TD and applying the result to the external power unit price EP as shown in the following equation. Is done.

For example, if the power requirement (TD) is 100 kwh, the internal power supply (IS) is 15 kwh, and the external power charge (EP) is 100 won / kwh, the modified power charge (CP) is 100 won / kwh * ( 100 kwh-15 kwh) / 100 kwh = 100 won / kwh * 0.85 = 85 won / kwh.

That is, the external power requirement ED (external power requirement ED / power requirement TD) relative to the electric power demand TD is a value having a range from 0 to 1, and may be referred to as an external power requirement ratio.

On the other hand, since the external power need is multiplied by the external power rate EP, the external power demand ED relative to the power demand TD can also be regarded as the actual recognition rate for the external power rate EP.

In the case of the previous example, the external power unit cost (EP) is 100 won / kwh, whereas the modified power rate (CP) is 85 won / kW, because the actual power rate is 0.85. kwh.

In other words, when the total power requirement is 100, 15% of the internal power is included, and thus, the internal power unit price corresponding to 15% becomes 0, so only the external power unit unit is recognized as 85%.

On the other hand, in the determination step of determining whether the external power required amount (ED) is 0 or more, if the external power required amount (ED) is 0 or 0 or less, the modified power rate calculation unit (see Fig. 5, 36) Determines the modified power rate CP to 0 (S807).

This is because if the modified power rate CP has a negative value, and if it is transmitted to the control unit (see FIG. 5 and 35) as it is, the control unit 35 may not understand the meaning, the lowest rate in terms of the rate concept. It is decided by the concept of 0 won / kwh.

On the other hand, for convenience, the description has been made by dividing into steps S804 to S807 and Equations 1 and 2, but the modified power rate information CP may be calculated in one step as shown in Equation 3 below.

Here, the external power requirements (ED) = power requirements (TD)-internal power supply (IS)

Where max (a, b) is the higher of a and b

By the Max operator, when the external power requirement ED has a negative value, the modified power rate information CP has a value of at least zero.

Hereinafter, referring to FIG. 8 and FIG. 9, the trend of the modified power rate CP will be described in detail.

First, referring to FIG. 9, since the internal power supply IS gradually increases from 0 to mid in a section from 0 to t1, the external power requirement ED is maintained at a similar level, so that the internal power supply IS Compared to the external power requirement (ED) (ie, the external power requirement mentioned above) gradually decreases.

In addition, the external power unit price EP is similarly maintained from 0 to the middle of the interval from 0 to t1 in the time section.

Therefore, since the external power required ratio gradually decreases and the external power bill information EP is maintained in a similar manner, the modified power bill information CP decreases from the middle of 0 to t1.

After the middle of 0 to t1, the external power required ratio gradually decreases, but since the increase rate of the external power rate EP increases, the decrease rate of the modified power rate information CP also falls.

On the other hand, in the section between t1 and t2, since the internal power supply amount IS precedes the power required amount TD and the external power required ratio is zero, the modified power rate information CP becomes zero.

As shown in FIG. 8, the modified power rate calculator (see FIG. 5) 36 of the present invention calculates modified power rate information CP through steps S804 to S807. The power requirement amount TD and the external power unit price EP are data that may change or be generated at predetermined time intervals, and may be updated or updated according to an update period.

Therefore, the step of calculating the modified power bill information CP may also be repeatedly performed at regular intervals according to the updated information.

Meanwhile, when the power requirement amount TD and the internal power supply amount IS are actual values corresponding to the current time, the modified power rate information CP corresponds to a real time power rate, and the power requirement amount TD and the internal power supply amount ( If IS) is a predicted value corresponding to a future time, the modified power rate information CP corresponds to the predicted power rate.

The modified power rate output unit (see FIG. 5, 37) transmits the calculated modified power rate information CP to the controller 35.

Then, the controller 35 performs a power saving function based on the modified power rate information CP.

For example, when the modified power rate information CP exceeds a predetermined criterion, the power saving mode may be performed, and when the modified power bill information CP exceeds the predetermined criterion, the power saving mode CP may operate in the non-sleep mode.

8 to 10, the process of calculating the modified power rate information CP is described as being performed in the energy management apparatus (see FIG. 5 and 30) in the present embodiment. However, this process may be performed in the electrical appliance itself. have.

Hereinafter, the control step after step S604 will be described with reference to FIG. 6.

After the modified power rate information CP is calculated in S604, first, it is determined whether the external power rate information EP exceeds a predetermined reference value (S605).

As a result of the determination, when the external power rate information EP is lower than a predetermined reference value, since the power rate is relatively inexpensive, the operation mode set by the user is performed as it is without performing a separate power saving mode (S610).

On the other hand, when the external power rate information EP exceeds a predetermined reference value in step S605, it is determined whether the modified power rate information CP exceeds the predetermined reference value (S606).

As a result of the determination in step S606, when the modified power rate information CP exceeds a predetermined reference value, the electrical appliance is controlled to operate in the first operation mode in which the power saving intensity is relatively high.

In particular, when there are a plurality of power consumption units, the power consumption of some or all of the power consumption units is reduced, or the performance thereof is limited or stopped (S607).

Alternatively, it is conceivable to reduce the power consumption of the power consumption of the plurality of power consumption units that is equal to or greater than a predetermined reference.

In addition, it is preferable that power of an auxiliary power source (self-generating facility, battery) is supplied to perform the first operation mode (S608).

However, if it is determined in step S606 that the modified power rate information CP does not exceed the reference value, the power saving mode is performed, but the electric appliance is controlled to be operated in the second operation mode having a lower power saving intensity than the first operation mode. (S609).

Even in this case, when there are a plurality of power consumption units in the electrical appliance, the power consumption of some of the power consumption units will be reduced, or the performance thereof will be limited or stopped, but the reduced strength or the limited strength will be determined by the first operation. It will be weaker than the mode.

The quantity, power rate, or driving time of the power consumption unit driven in the second driving mode may be greater than the quantity, power rate, or driving time of the power consumption unit driving in the first driving mode.

Then, each electrical product supplies the power of the auxiliary power source (self-generation facility, battery) (S610). At this time, the power supplied from the auxiliary power source is preferably supplied to the low power consumption unit of which the power consumption is less than a predetermined reference.

In FIG. 10, when the first operation mode is performed, it is a time period from 0 to t3. In this case, the external power rate information EP and the modified power rate information CP both exceed a reference rate.

When the second operation mode is performed, it is a time period from t3 to t4. In this case, the external power charge information (EP) exceeds the reference charge, but the modified power charge information (CP) is lower than the reference charge. to be.

On the other hand, it is determined whether the forced control command is input from the load control device while the electrical appliance is operating in the first or second operation mode or the user setting mode.

Here, the load control device is operated in the form of a server, and at this time, a unique ID is provided for each power demand destination and each electric power demand destination. Therefore, the load control device can search for a specific ID and issue a load control command to the power demander and the electric appliance having the same.

When a forced control command is input, the current operation mode is interrupted and the forced power saving operation mode is performed according to the forced control command of the load control device (S702 and S703).

As described above, the reason for controlling the forced power saving operation mode is to prevent a power outage in the entire power grid due to insufficient power supply when the power consumption temporarily increases in a plurality of power demands.

Therefore, reducing the power consumption for a certain time regardless of the power usage intention of each power source is the core of this control flow.

Here, the forced power saving operation mode will be stronger than the first operation mode in the present invention, even in this case, the power consumption of some or all of the plurality of power consumption units is forcibly reduced, so that the performance of the power consumption unit is limited. do.

Alternatively, the performance of the power consumption unit that consumes a relatively high amount of power among the plurality of power consumption units or the power consumption unit that consumes a predetermined reference power or more may be limited, and the driving time thereof may be limited.

Alternatively, it is conceivable that some of the power consumption units are driven and other power consumption units are temporarily stopped.

Alternatively, while maintaining the power consumption of electrical appliances such as refrigerators that require constant driving, the power consumption of the electrical appliances, such as washing machines or dryers, may be stopped or the power consumption may be reduced. .

Through such a forced power saving operation mode, it is possible to suppress a sudden increase in the amount of power consumed by temporary concentration of power demand.

On the other hand, after a predetermined time has elapsed, it is determined whether the forced control end command has been input (S704), and in such a case, the control according to the forced control command is terminated, and the operation mode immediately before the forced control command input is performed again ( S705).

A sequential control flow between the utility company / load control device and smart devices will be described with reference to FIG. 11.

Here, the control of the electrical appliance is shown through the mediation of the energy management device or the smart server controlling the electrical appliance.

However, the control unit, the interface unit, the modified power rate information calculating unit, the modified power rate information output unit, etc. are provided in the indoor unit and / or the outdoor unit, so that the indoor unit and / or the outdoor unit can be operated by the indoor unit and / or the outdoor unit itself. Can be done.

In addition, when the indoor unit and / or the outdoor unit can be controlled by itself, the controller or interface unit, the modified power rate information calculating unit, and the modified power rate information output unit are provided as separate external components from the indoor unit and / or the outdoor unit, and the power rate information. May be calculated or a forced control command may be received.

First, when an electric power company transmits an external power rate, the energy management device or smart server grasps an internal power supply and calculates corrected power rate information based on this.

Then, a control command based on the external power fee information and the modified power fee information is transmitted to the electrical appliance. In this case, the control command may be to control the electric appliance to be driven in the first and second operation modes or the user setting mode for power saving.

The electrical appliance receives this control command and performs an operation based on the control command, and transmits the current electrical appliance status to the energy management device or smart server.

Accordingly, the energy management device or the smart server can continuously observe the current state information (power consumption information, driving mode information) of the electrical appliances.

On the other hand, when the electrical appliance is operating in a specific operation mode, when it is recognized that the need to suppress the power consumption due to the sudden increase in power consumption, forced control of the load control device is transmitted to the energy management device or the smart server.

The energy management device or the smart server receiving the forced control command instructs the current operation mode to be stopped for the specific electrical appliance, and transmits a control command to the corresponding electrical appliance to perform the forced power saving operation mode according to the forced control instruction.

The electrical appliance that has received the command regarding the forced power saving operation mode stops the current operation mode accordingly and performs the forced power saving operation mode.

The state information of the electric appliance according to the forced power saving operation mode is transmitted to the energy management apparatus or the smart server.

Then, the energy management device or smart server transmits the state information about the home power state to the load control device, so that the load control device can observe the current power state.

Subsequently, when the reason for canceling the forced control command such as the power supply amount is sufficient compared to the power demand, or the forced control situation is released after a predetermined time elapses, or the forced control termination command is input, such forced control termination A command is sent to the energy management device or smart server.

The energy management device or the smart server which has received the forced control end command issues a forced power saving end command to the specific electric appliance that is currently performing the forced power saving operation, and commands the operation mode immediately before the forced power saving operation to be performed.

Accordingly, the electric appliance ends the forced power saving operation mode and resumes the operation mode immediately before that.

Then, the state information related to the current operation mode being performed in the electrical appliance is transmitted to the energy management apparatus or the smart server.

In FIG. 11, when direct communication is performed between the electric company or the load control device and the electric appliance, the role of the energy management device or the smart server in the above description will be performed by the interface unit and the control unit, and their commands are performed in each electric appliance. The power consumption unit will perform.

Therefore, various forms of power saving operation for a smart device including an electrical appliance or an energy management device may be performed through the control flow.

30: energy management device 34: interface unit
34a: External power bill information receiver 34b: Internal power supply detector
34c: required amount acquisition unit 35: control unit
36: modified power bill information calculating unit 37: modified power bill information output unit
100: electrical appliances 101e ~ 104e: first power consumption unit
101f to 104f: second power consumption unit

Claims (14)

In a smart device for monitoring and controlling the operation of electrical appliances,
An interface unit for recognizing external electric power charge information and an external forced control command for the electric appliance, and recognizing the amount of available electric power of an auxiliary power source in the home;
Is connected to the interface unit, and controls the operation of the electrical appliance based on the external power rate information and the modified power rate information derived based on the ratio of the available power of the auxiliary power to the power requirements of the home, And a control unit for controlling the electric appliance based on the forced control command in preference to the control command based on the revised power rate information. The method of claim 1,
The control unit stops the operation control of the electrical appliance based on the modified power rate information when the mandatory control command is input during the operation control of the electrical appliance based on the modified power rate information, and controls the control command of the load control device. Smart device, characterized in that for controlling the operation of the electrical appliance based. The method of claim 1,
The controller determines whether the received external power bill information and the modified power bill information exceed a predetermined reference value,
When the external power bill information and the modified power bill information exceeds a predetermined reference value, the electrical appliance controls to perform the first operation mode,
When the external power bill information exceeds a predetermined reference value, and the corrected power bill information is less than a predetermined reference value, the electric appliance controls to perform a second operation mode in which power consumption is greater than that of the first operation mode. Smart device. The method of claim 2,
The control unit is a smart device, characterized in that for controlling the internal power supply amount of the auxiliary power source when performing the second operation mode of the electrical appliance. The method of claim 4, wherein
The first driving mode is a smart device, characterized in that to limit the performance of at least one of the plurality of power consumption unit or to stop the operation. The method of claim 3,
Smart device, characterized in that for limiting the performance of the power consumption unit having a relatively high power consumption or consumes more than a predetermined reference power of the plurality of power consumption unit in the first operation mode. The method of claim 4, wherein
Smart device, characterized in that the quantity or power rate or driving time of the power consumption unit is driven in the second driving mode is greater than the quantity, power rate or driving time of the power consumption unit is driven in the first driving mode. The method of claim 4, wherein
Smart device, characterized in that the power supplied from the auxiliary power supply when performing the second operation mode is supplied to a low power consumption unit that the power consumption is less than a predetermined reference. The method of claim 1,
The correction power bill information calculation is calculated in consideration of the ratio of the power supplied from the system power associated with the external power bill information and the power supplied from the auxiliary power available at a lower price than the external power bill information. Smart devices. The method of claim 3,
The controller controls the power consumption of the electrical appliance according to the control command of the load control device to be less than the power consumption according to the first driving mode. The method of claim 1,
The modified power rate information is calculated by multiplying the ratio of the required amount of external power to the required amount of power in the home by the power rate information per unit time. The method of claim 11,
The power required amount, the available power amount of the auxiliary power source, and the external power rate information are received or obtained at a predetermined unit of time, and the modified power rate information is calculated at a predetermined unit of time. The method of claim 1,
The smart device is provided in the electrical appliance, or a smart device, characterized in that provided as a separate component from the electrical appliance. The method of claim 1,
A modified power rate information calculating unit provided in the electric product or provided as a separate component from the electric product, communicable with the interface unit, and calculating the modified power rate information;
The modified power rate information provided in the electrical product or provided as a separate component from the electrical product, and provided to communicate with the modified power rate information calculating unit and the controller. Smart device characterized in that it further comprises a modified power rate calculator for outputting to the control unit.

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