KR20120000295A - Control method for electric device - Google Patents

Abstract

PURPOSE: A control method for an electric device is provided to performs effective management of power supply magnetic power demand. CONSTITUTION: An on-peak time interval and an off-peak time interval are recognized(S13). At least one type of power information including an electricity charge in the on-peak time interval accesses the predetermined value. In the off-peak time interval, at least one type of power Information is under the designated value. Whether a driving allowable time interval of the electrical appliance exists or not in the on-peak time interval is determined (S30). At least one part of the driving time of the electronic product in the driving allowable time interval is included(S50,S511,S531).

Description

Control Method for Electric Products

The present invention relates to a control method of an electric product.

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 power plants operated by KEPCO, transmission lines, and wiring lines. to be.

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 (Smart Grid) 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 and 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, enabling interaction between consumers and suppliers. , Distributed 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 a power consumer such as a home or a building, it is necessary to bi-directionally communicate with a power supply source and power information, instead of unilaterally receiving power from individual electric appliances and a network to which a plurality of electric appliances are connected. And the need for new devices for this two-way communication.

In addition, when using electric appliances in real time to determine the electricity bill, and when the electricity rate is high, the control method of the electrical appliances that can save energy and electricity bills by inducing to refrain from using electrical appliances. Necessity was raised.

The present invention has been made to solve the problem of providing a control method of the electric product capable of efficiently managing the power demand by the electric power supplier, and the consumer can reduce the electricity bill and energy consumption by eliminating the concentration of power demand.

According to an aspect of the present invention, there is provided a method for recognizing an on-peak time interval in which at least one or more power information including an electric charge exceeds a predetermined value and an off-peak time interval that is less than or equal to the predetermined value. Determining whether a driving allowable time interval of the electrical appliance is present in a peak time section, and controlling the at least part of a driving time of the electrical appliance to be included in the driving allowable time interval. do.

In this case, the driving allowable time interval may be a time interval in which the power consumption information value expected when the electrical appliance operates within the on-peak time interval becomes less than a predetermined standard.

The power consumption information value may be any one of an electric charge, a power consumption amount, and an operation time.

The predetermined criterion may be any one of a predetermined ratio of a driving time set in the electrical appliance, a constant ratio of a power consumption amount, or a constant ratio of an electric charge.

In this case, the predetermined criterion may be set by a user, or by a control unit controlling the driving of an electric product using the power information, or by a power supply source providing the power information.

The predetermined criterion may be a specific value of any one of a driving time, an electric charge, and a power consumption of the electrical appliance.

In this case, the predetermined criterion may be set by a user, or by a control unit controlling the driving of an electric product using the power information, or by a power supply source providing the power information.

On the other hand, the driving allowable time period is characterized in that the start allowable period in which the driving of the electrical product is started, the start allowable period includes the end point of the on-peak time interval, but the time interval before the off-peak time interval It may be characterized by.

In this case, the predetermined criterion may be a period of time equal to or less than a predetermined ratio of the driving time set in the operation mode provided in the electrical appliance.

In addition, the electric product may be driven only when the expected power consumption is less than a predetermined reference value when the operation mode is executed within the start allowable period.

In addition, when the operation mode is executed within the start allowable period, the electric product may be driven only when the expected electric charge is less than or equal to a predetermined reference value.

The predetermined criterion may be a time section in which an expected power consumption amount is less than a predetermined reference value when the operation mode provided in the electrical product is executed in the on-peak time section.

The predetermined criterion may be a time section in which an electric charge expected when the operation mode provided in the electric product is executed in the on-peak time section is less than or equal to a predetermined reference value.

On the other hand, the driving allowable time period is characterized in that the end of the allowable driving period of the end of the electrical appliance, the end allowable period including the starting point of the on-peak time interval, but the time interval after the off-peak time interval It may be characterized by.

In this case, the end allowable section may be a time section less than a predetermined ratio of the driving time set in the operation mode provided in the electrical appliance.

In addition, the electric product may be driven only when the expected power consumption is less than a predetermined reference value when the operation mode is executed within the end allowable interval.

In addition, the electric product may be driven only when the expected electric charge is less than or equal to a predetermined reference value when the operation mode is executed within the end allowable section.

The end allowable section may be set to a time section in which the power consumption expected when the operation mode provided in the electrical appliance is executed in the on peak time section is less than or equal to a predetermined reference value.

On the other hand, the driving allowable time period includes a start allowable period in which the driving of the electrical appliance is started and an end allowable period in which the driving of the electrical appliance is terminated, and the driving allowable time interval is the electric product in the start allowable interval. In the case of driving, the sum of the expected power consumption information value and the expected power consumption information value when the electrical appliance is driven in the end allowable period may be characterized in that the time interval is less than the predetermined criterion.

On the other hand, the step of recognizing the on-peak time period and the off-peak time interval is recognized by comparing the power information provided to the electrical appliance and the predetermined value set in the electrical appliance, or is provided on the outside of the electrical appliance It may be characterized by being recognized by the information of the peak time period and the off-peak time period.

On the other hand, the driving allowance period is characterized in that the driving allowance period is a partial driving allowance period is maintained for a predetermined time, the partial driving allowance section is the start allowance period including the start point of the on-peak time interval and the It may be characterized in that it is a time interval provided between the end allowable interval including the end point of the on-peak time interval.

According to the control method of the home appliance according to the present invention, by eliminating the concentration of power demand, the power supplier can efficiently manage the power demand, the consumer can provide a control method of electrical appliances that can reduce the electricity bill and energy consumption The effect can be aimed at.

1 is a conceptual diagram of a smart grid.
2 is a schematic diagram of a home power supply network.
3 is a front view of the energy management apparatus.
4 is a control block diagram of a power supply and home power supply network system.
5 is a control block diagram according to another embodiment of a power supply network system.
6 is an example of power information used in the control method of the electrical appliance of the present invention.
7 and 8 are a control block diagram showing a control method of the electrical appliance of the present invention.
9 is a control block diagram showing another embodiment of the method for controlling an electrical appliance of the present invention.

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

Unless defined otherwise, all terms herein are the same as the general meaning of the term as understood by one of ordinary skill in the art to which this invention belongs, and if the terms used herein conflict with the general meaning of the term Are as defined herein.

On the other hand, the configuration or control method of the device to be described below is not intended to limit the scope of the present invention, but to describe the embodiment of the present invention, the same reference numerals are used throughout the specification the same components Indicates.

Hereinafter, with reference to the accompanying drawings will be described in detail a clothing processing apparatus according to an embodiment of the present invention.

However, names and symbols of the components are defined in consideration of the functions in the present embodiment, it should not be understood as a meaning limiting the technical components of the present embodiment.

1 is a schematic diagram of a smart grid. Referring to FIG. 1, the smart grid includes a power supply source that generates power through thermal power generation, nuclear power generation or hydroelectric power generation, and a power supply source including a solar power plant using solar or wind power belonging to renewable energy and a wind power plant. do.

The thermal power plant, nuclear power plant or hydroelectric power plant may send power to a power plant through a transmission line, and the power plant may supply electricity to a substation and a storage device. In addition, the electricity produced in photovoltaic power plants and wind power plants can be supplied to substations.

On the other hand, the electricity transmitted to the substation can be distributed to the office or each home via the power storage device.

On the other hand, in the case of adopting a home electric power network (HAN, home area network (described in detail in FIG. 2)), even in a normal home is installed in a self-solar power generation facility of the general home, or a PHEV (plug in hybrid electric vehicle) The fuel cell can supply its own electricity and the extra electricity can be sold back to the outside.

In addition, the office or home may be provided with a so-called 'smart measuring device' that can grasp the power and electricity bills used in each demand in real time. Through the smart measurement device, the user can recognize the amount of electricity and the electricity bill currently used, and can devise a method of reducing the power consumption or the electricity bill according to the situation.

On the other hand, demand sources using the aforementioned power plants, power stations, storage devices and power in the smart grid are capable of bidirectional communication. Therefore, apart from allowing the customer to receive electricity unilaterally, the situation of the customer can be notified to the storage device, the power station, and the power plant so that electricity can be produced and distributed according to the situation of the customer.

Therefore, the smart grid requires an energy management system (EMS), which is responsible for real-time power management and real-time prediction of power consumption, and an advanced metering infrastructure (AMI) that measures power consumption in real time. do. The energy management device and the measurement device may be configured as separate devices, or may be configured to perform the functions of both devices in one device.

Instrumentation under Smart Grid is a foundation technology to integrate consumers based on 'open architecture', enabling consumers to use electricity efficiently, and power providers to detect system problems and operate the system efficiently. Provide the ability to Here, 'open architecture' refers to a standard that allows all electric devices to be connected to each other regardless of the manufacturer of the electric device in the smart grid system, unlike a general communication network.

Thus, the instrumentation used in the smart grid enables a consumer friendly efficiency concept such as "Prices to Devices." That is, real-time price information of the power market can be transmitted through an energy management device (EMS) installed in each home, and the energy management device (EMS) communicates with and controls electrical devices (such as home appliances) provided in each home. can do.

Accordingly, the user can save power and energy by recognizing power information of each electric device by the energy management device (EMS) and performing power information processing such as power consumption amount or electric charge limit setting based on the power information. The above-described energy management device (EMS) is a local energy management device (Local EMS) used in the office or home, information collected by the local energy management device (Local EMS) by bidirectional communication with the local energy management device (EMS) It can be configured as a central energy management device (Central EMS) for processing.

In addition, since the smart grid enables real-time communication about power information between the power supplier and the consumer, it is possible to react to various consumers according to the power supply, that is, "real-time electric grid response" unlike the conventional art.

For example, when the price of power varies according to time zones or the price of power varies depending on the power supply company, the consumer can change or adjust the power consumption or power consumption time in consideration of such conditions.

In addition, the power supplier can adjust the power price or the amount of power supply according to the response of the consumer.

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

Referring to FIG. 2, the power supply network system 10 includes a measuring device (smart meter, 20), a measuring device 20, and a home appliance that can measure power and / or electricity rates supplied to each home in real time. It may be provided with an energy management device 30 is connected to the same plurality of electrical appliances and control their operation.

On the other hand, the electricity bill of each household is charged as an hourly rate, and the hourly electricity bill is expensive in a time section in which the power consumption is rapidly increased, and the hourly electricity bill may be cheaper at night time, such as a relatively low power consumption. .

The energy management device 30 is connected to electrical appliances such as a refrigerator 101, a washing machine and a dryer 102, an air conditioner 103, a TV 105, or a cooking appliance 104 through a network in the home, thereby bidirectionally communicating. can do.

Communication at home may be via wireless or wired, such as a PLC, and one household appliance may be connected to communicate with other household appliances.

Referring to FIG. 3, the energy management apparatus 30 may include a display unit 31 displaying power information and / or external environmental information, an input unit 32 that may be operated by a user, and a communication unit that transmits and receives information with an external device ( 34, see FIG. 4), a watch 40 (see FIG. 4), and a controller 35 (see FIG. 4).

For example, the energy management device 30 may include a touch panel 33 and a display unit 31 on the touch panel 33. The display unit 31 may display power information and / or external environment information.

The power information includes current electricity usage, electricity rates, estimated charges based on accumulated history, energy information of the day, such as carbon dioxide generation, electricity rates for the current time zone, electricity rates for the next time period, and electricity rates. It may include at least one of the real-time energy information including the time interval.

In addition, the external environment information may include at least one of information such as current weather, temperature, humidity, precipitation, wind. In addition, the display unit 31 may display a graph indicating power consumption and / or a change in time periods of each home appliance, and a graph of electricity rate trends for each time period may also appear.

One side of the display unit 31 may be provided with an input unit 32 that allows the user to set the operation of the electrical appliance, if necessary. The user may set a limit of the amount of electricity or the electric charge of each home appliance by using the input unit 32, and the energy management device 30 may control the operation of each home appliance according to the setting.

The communication unit 34 may include a refrigerator 101 (refer to FIG. 4), a washing machine 102 (refer to FIG. 4), an air conditioner 103 (refer to FIG. 4), and / or a cooking appliance 104 (refer to FIG. 4). It communicates with electrical appliances and transmits and receives their power information (power consumption information value) and driving information.

The control unit 35 grasps the setting information input by the user by the input unit 38, the operation and power usage history information of the existing home appliances, and the amount of power supplied from the outside in real time, and processes the information in real time. The operation and power consumption of home appliances can be controlled.

FIG. 4 is a block diagram showing a control block diagram of a power supply network system for supplying power to a power supply under a smart grid and electric appliances in a home.

Referring to FIG. 4, the power supply source may be a power company 50 having general power generation equipment (firepower, nuclear power, hydropower) or power generation equipment using renewable energy (solar, wind, geothermal), and the like. have. In addition, the power supply source may include a self-photovoltaic facility 51 that may be provided in each home, and a fuel cell 52 that may be provided in a fuel cell vehicle or a home.

The power supply source is connected to the measuring device 20, and the measuring device 20 is connected to the energy management device 30. However, when the measuring device and the energy management device are configured as one module, it is sufficient that the power supply source is connected to the module so as to be able to communicate with the measuring device or the energy management device.

As described above, the energy management device 30 may include a control unit 35, an input unit 38, a communication unit 34, a display unit 39, and a clock 40.

The energy management device 30 and the control unit provided in each electric product control each electric product by interworking with each other. Specifically, an electric charge saving mode and power consumption for saving electric charges when the electric product is operated. It is possible to provide an energy saving mode that can save energy.

Electricity saving mode is operated based on the information on the electricity rate which depends on the time the appliance is operated. For example, the controller 35 may determine the electric charge of the current time interval by using the clock or the timer 40.

That is, the control unit 35 is a time period when the current electric charge exceeds a predetermined electric charge criterion (reference rate), that is, whether the first time interval (on peak time period) or less than the predetermined electric charge criterion, i.e. It can be determined whether it is a two-hour period (off-peak time period).

In addition, when it is determined that the current time belongs to the first time section (on peak time section), the controller 35 may also inform how much time is left to enter the second time section (off peak time section). .

On the other hand, in the case of the energy saving mode, the effect is equivalent to the technical effect caused by the mode set by the user or the effect does not have a big difference, but guides or enforces the saving mode to reduce the power consumption.

For example, if the electrical appliance is a washing machine, if the amount of laundry contained in the washing machine is relatively small even if the user selects the standard operation mode, the control unit provided in the energy management device and the electrical appliance is more than the standard operation mode. The washing machine can be controlled in another operating mode (e.g., quick run mode) which consumes less power.

In this case, the amount of washing water consumed by the washing machine, the total driving time and drying time of the washing machine, and the amount of power consumed by the heater will be reduced compared to the case of the standard course.

However, the energy saving mode may be provided in a manner of changing the output of the home appliance in the first time section (on peak time section) and the second time section (off peak time section).

That is, the electric appliance controlled in the energy saving mode is driven according to the output set in the operation mode selected in the second time section (off peak time section), but in the first time section (on peak time section), the second time section ( It may be controlled to have an output lower than the output of the off-peak time period or lower than the output set in the selected operation mode.

For example, an electric appliance such as a refrigerator, in the energy saving mode, the refrigerator is controlled to generate a lot of cool air when the driving time is in the second time period (off-peak time period), but the driving time is in the first time period (on If it is within the peak time period, it can be controlled to generate a small amount of cold air (the function of the refrigerator must be controlled to be maintained by the cold air accumulated through the overpower control).

The energy saving mode or the electricity saving mode described above is controlled by the energy management device 30 provided independently of the electric product. However, unlike FIG. 4, the energy management device 30 is detachable from the electric product. It is not intended to exclude those provided in the form or integrally provided in the electrical appliance.

That is, the energy management device 30 may be integrally provided with the electrical appliance that continues to operate for 24 hours, such as a refrigerator (see FIG. 5).

However, since the refrigerator is only one example, the energy management device may be provided in any electric product as long as the product operates for 24 hours.

On the other hand, when the energy management device 30 is detachably provided in the refrigerator 101, the control unit 35 of the energy management device 30 is the control unit 101a of the refrigerator and the measurement device ( 20) can transmit and receive information by wire or wirelessly.

In addition, the control unit 35 may exchange and control various kinds of information such as other electric appliances, for example, a washing machine 102, an air conditioner 103, or a cooking appliance 104 through the communication unit 34. .

FIG. 6 is an example of power information provided to an electric product, and the power information of FIG. 6 provides electricity rate information that changes with time. However, since the electric charge is only one example of power information, various forms can be distinguished between an on-peak time period in which power demand is concentrated and an off-peak time period in which power demand is less concentrated. May be received as power information.

The on-peak time period may be defined as a time period in which the electric charge exceeds a predetermined value (S), and the off-peak time period may be defined as a time period in which the electric charge is less than or equal to the predetermined value (S).

The predetermined value S may be defined in various forms, including an average value of the electric charge provided in the power information, an average value of the electric charge after the scheduled execution of the electric product, and a maximum of the electric charge after the scheduled execution of the electric product. An example may be an average value of a value and a minimum value.

The predetermined value S may not be a value calculated through the power information, but may be defined in a manner in which a user or a controller of an electric product sets an arbitrary electric charge.

Accordingly, the on-peak time period means a time period in which the electric product can be driven at a relatively expensive electric charge, and the off-peak time period means a time period in which the electric product can be driven at a relatively low electric charge.

On the other hand, from the standpoint of the power supply source, since the on-peak time period is a time period in which the power demand is concentrated, it has a meaning that it is a time period that needs to be distributed to the off-peak time period.

Referring to one example of the power information disclosed in FIG. 6, in order to solve the power demand concentration and reduce the electric charge, it is preferable to drive the electric product only in the off-peak time period.

However, there may occur a case where the operation mode of the electrical appliance is not started and completed within the off-peak time period. In this case, the remaining stroke of the operation mode that does not end within the off-peak time period may be controlled to be delayed to the next off-peak time period.

That is, the operation mode provided in the electrical appliance may be set to perform a single stroke, but a plurality of strokes are generally provided in a combined form in a certain order. Therefore, if the initial administration provided in the operation mode is controlled to start at the off-peak time period, but the remaining strokes at the end of the off-peak time period are controlled to be executed at the next off-peak time period, From the standpoint, it will be possible to reduce the electricity bill and reduce the concentration of electric power demand.

However, controlling the electric appliance to be driven only during the off-peak period may cause a problem of deteriorating the convenience of the electric appliance.

A plurality of strokes set in the operation mode are combined in a certain order, and in some cases, electric appliances can achieve the intended performance when continuity is ensured in the order of the combination. Therefore, if the electrical appliance is controlled by simply ignoring the continuity of administrations to drive the electrical appliance only in the off-peak time period, the performance of the electrical appliance may be degraded or the user may not complete the selected operation mode within the desired time.

Accordingly, the present invention not only controls the electric product to operate within the off-peak time period, but also drives the electric product if the driving allowable time period exists in the on-peak time period located before and after the off-peak time period. I want to solve the problem.

The driving allowance time period may be divided into a start allowance period and an end allowance allowance for driving an electric product as a time period belonging to an on-peak time period.

The start allowable period belongs to the on-peak time period but is provided before the off-peak time period, and the end allowable section belongs to the on-peak time period and is provided after the off-peak time period. .

That is, the driving allowable time period is disadvantageous compared to the case in which the electric product is driven in the off-peak time period based on power information such as an electric charge, but when the certain requirements are satisfied, the time for which the electric product is selectively allowed It is defined as an interval.

In more detail, the driving allowable time interval is a time interval in which an estimated power consumption information value (electric charge, power consumption, or driving time, etc.) is assumed to be driven within the on-peak time interval. Can be set.

Here, the power consumption information value refers to data on power information consumed by the electrical appliance, and corresponds to a concept corresponding to the power information provided to the electrical appliance.

That is, if the power information provided to the electrical product is an electric charge, the power consumption information value means an electric charge imposed by driving the electric appliance.

On the other hand, the predetermined criterion may be a constant ratio of the driving time set in the electrical appliance (eg, the driving time set in the operation mode of the electrical appliance), or a constant ratio of the power consumption required when driving the electrical appliance for the predetermined driving time, or It may be set to a relative value of the power consumption information value, such as a certain percentage of the electric charges charged when the electrical appliance is driven for a set driving time.

Accordingly, the driving allowable time interval may be defined as a time interval within an on-peak time interval corresponding to a predetermined ratio (eg, 10%) of the total driving time set in the electrical appliance (time set in a specific operation mode of the electrical appliance). For 100 minutes, the time period equivalent to 10 minutes in the on-peak time interval).

In addition, the driving allowance time period is a percentage of the electric charges charged when driving the electrical appliance during the driving time set in the operation mode of the electrical appliance is charged when the electrical appliance is driven in the on-peak time interval ( For example, it can be defined as a time period of 10% or less (a time period in which an electric charge of less than 10 won is charged within the on-peak time period when an electric charge is charged 100 won when executing a specific operation mode of an electric appliance).

In addition, the driving allowance time interval is a predetermined ratio of the amount of power consumed when driving the electrical appliance during the driving time set in the operation mode of the electrical appliance, the amount of power consumed when driving the electrical appliance in the on-peak time interval (eg, It can be defined as a time period of less than 10%) (a time period in which less than 10Wh of power is consumed in the on-peak time period when the expected power consumption when the operation mode of the electrical appliance is executed is 100Wh).

The predetermined criterion may be set to a specific value of a driving time, a specific value of an electric charge, and a specific value of a power consumption amount.

In this case, the driving allowance time period is a time period that does not exceed a specified driving time (eg, 10 minutes) within the on-peak time period, and when the electric product is driven in the on-peak time period, the electric charge is a specific value (eg, The driving time period of the electrical appliance does not exceed 2000 won), and when the electrical appliance is driven in the on-peak time interval, it means the driving time period of the electrical appliance whose power consumption does not exceed a specific value (10Wh).

Meanwhile, the above-described 'schedule criteria' may be set by the user inputting to the electrical appliance, the controller controlling the electrical appliance may be set by itself in consideration of the power information or the selected operation mode, or a power supply source for providing the power information. May be set.

Therefore, although the driving allowable time interval is a time interval provided in the on-peak time interval, the user can minimize the disadvantages such as electric charges from the user's point of view, and the power supply source can solve the concentration of power demand to some extent. It is a time interval.

On the other hand, as described above, the driving allowance time period is a concept including a start allowance section and an end allowance section. Therefore, the setting of the start allowance section and the end allowance section may be performed based on the same criteria as the setting of the driving allowance time section.

That is, the start allowable interval may be defined as a time interval in which the expected power consumption information value is less than a predetermined standard when the electric appliance is driven within the on peak time interval, and the end allowable interval is within the on peak time interval. When the electrical appliance is driven, it can be defined as the time when the expected power consumption information value falls below a certain standard.

However, the start allowable period is present in the on-peak time period, but is provided before the start point of the off-peak time interval is a time interval that can start the operation of the electrical product, the end allowable interval is present in the on-peak time interval, but off It is distinguished in that it is provided after the end point of the peak time period and is a time period in which the driving of the electrical appliance can be terminated.

Further, the driving allowable time interval is such that the sum of power consumption information values when the electrical appliance is driven in the start allowable interval and power consumption information values when the electrical appliance is driven in the end allowable interval does not exceed the above-mentioned predetermined criterion. It may be set to a time interval. In this case, the size of the start allowance section and the end allowance section may be adjusted according to the characteristics of the initial stroke and the final stroke of the operation mode set in the electric appliance.

Therefore, if the first stroke of the operation mode is a stroke with high power consumption and the last stroke is a stroke with low power consumption, the size of the start allowance section is set relatively smaller than the size of the end allowance section, but each stroke of the operation mode is continuously Controls that can be made will enable more efficient control of the driving of electrical appliances.

The above-described driving allowable time interval is a time interval (end allowable interval) in which driving starts (starting allowable interval) and end of driving within the on-peak time interval is possible. Therefore, the present invention starts to drive an electric product within an off-peak time interval. And control method in which the operation is started, the start of the driving period is started, the control method in which the operation of the electrical appliance is terminated in the off-peak time period, the drive of the electrical appliance is started in the off-peak time period, the drive of the electrical appliance in the end allowable section It is possible to provide a control method in which the control method is terminated and the driving of the electrical appliance is started in the start allowable section and the driving of the electrical appliance is terminated in the termination allowable section.

FIG. 7 is a control block diagram illustrating a control method of an electric product. Hereinafter, a control method of an electric product provided with power information from a power supply source will be described with reference to FIG. 7.

The control method of the present invention proceeds to step S10 of recognizing the on-peak time period and the off-peak time period by comparing the power information with a predetermined value (S, see FIG. 6).

The power information may be defined as data capable of distinguishing an on-peak time period in which power demand is concentrated and an off-peak time period in which power demand is less concentrated. Hereinafter, the power information will be described. The case where the content of the above is an electric charge described as an example.

Meanwhile, in the step S10 of recognizing the on-peak time period and the off-peak time period, the electrical appliance receives power information from a power supply (S11) and then receives the predetermined value S set in the electrical appliance. It can proceed by comparing with (S13).

If the power information is provided in the form of an electric charge, the predetermined value S will be predetermined electric charge data input by a user, a controller of an electric appliance, and the like.

However, the electrical appliance compares and analyzes the power information with a predetermined value to determine the on-peak time period and the off-peak time period, and the information of the on-peak time period and the off-peak time period is directly from the outside of the electrical product. It does not exclude the case provided by.

That is, a power information provider located outside of the electrical appliance, such as a power supply, may directly provide all the information of the on-peak time period and the off-peak time period to the electrical product.

If it is determined that the received power information is an off-peak time period that is less than or equal to the predetermined value S, the control method of the present invention controls the electric product to drive the electric product in the off-peak time period (S40).

However, when it is determined that the received power information is an on-peak time period exceeding the predetermined value S, the control method of the electrical appliance of the present invention determines whether or not a driving allowable time period exists within the on-peak time period (S30). do.

As described above, the driving allowable time interval may be based on a predetermined criterion (eg, electricity rate, power consumption, driving time, etc.) that is expected when the electric appliance is driven within the on-peak period. It is a period of time that is less than or equal to the specified electricity rate.

Accordingly, in the step S30 of determining whether the driving allowable time interval exists, the time interval when the power consumption information value (electric charge, etc.) expected when the electrical appliance is driven within the on-peak time interval becomes less than the predetermined criterion. It is a step of determining whether there exists.

If there is a driving allowance time interval, the control method of the present invention proceeds to step S50 of determining whether the driving allowance time interval is a start allowance interval and whether an end allowance interval exists.

Of course, the step (S50) may be provided to individually determine whether or not there is a start allowance section, whether there is an end allowance section, whether there is both a start allowance section and an end allowance section.

The start allowance section may be provided in the on-peak time section, but may be set to include an end point of the on-peak time section as shown in FIG. 6 as a time section located before the off-peak time section, and the end allowable section is off. The on-peak time period following the peak time period may be set to include the starting point of the on-peak time period as shown in FIG. 6.

On the other hand, when the driving allowable time period includes both the start allowable period and the end allowable period, the control method of the present invention starts the operation of the electrical appliance in the start allowable period, but the off-peak time period or the end allowable period of the electrical appliance It is preferable to control the electrical appliance (S531) so that the drive is terminated.

However, in the case where the start allowable section or the end allowable section exists within the driving allowable time section (S50, No), the control method of the present invention proceeds as follows.

The control method of the present invention controls the electrical appliance to start the operation of the electrical appliance in the start allowable interval if the driving allowable time interval is the start allowable interval (S511), and the control method of the present invention if the driving allowable time interval is the end allowable interval. In step S511, the electrical appliance is controlled such that the driving of the electrical appliance is terminated in the end allowable section.

That is, in the case where the driving allowable time interval is a start allowable period, the control of the electrical appliance is started so that the driving of the electrical appliance starts in the start allowable interval and ends within the off-peak time interval, and the driving allowable time is the end allowable interval. In the off-peak period, the driving of the electrical appliance is started and the electrical appliance is controlled to end the driving within the allowable termination period.

Therefore, the control method of the present invention enables the operation of the electric product while minimizing the disadvantage of the electric charge even during the on-peak period.

Furthermore, the control method of the present invention may further include the step (S51, S53) of determining whether or not the start allow mode (or whether the end allow mode) (see Fig. 8).

The start allowance mode (or end allowance mode) is a concept that is meaningful when the drive allowance time interval is set to be equal to or less than a predetermined ratio of a drive time set in an electrical appliance or below a specific drive time.

Suppose that a time period corresponding to a predetermined ratio (eg, 10%) or a specified driving time (eg, 10 minutes) of the driving time set in the electric product during the on-peak time period is set as the driving allowable time period.

In this case, if the driving mode of the electrical appliance driving within the driving allowance time period requires a large amount of power, the driving allowance time interval will consume a lot of power even though the driving allowance time period is relatively short, such as reducing electric charges. Contradictions may arise that are difficult to achieve the objects of the present invention.

Therefore, the step (S51, S53) of determining whether the start allowable mode or the end allowable mode is when the electric product is driven within the start allowance section or the end allowance section is less than a predetermined reference value power consumption (or electric charge) It may be defined as a step of determining whether or not.

On the other hand, when the start allowable section or the end allowable section is provided within the driving allowable time interval, the operation S511 is performed if the operation mode of the electrical appliance is the start allowable mode or the end allowable mode, but otherwise, the operation mode of the electric appliance is not executed. It is preferable that the control mode is controlled so as to execute the operation mode in the off-peak time period.

However, if both the start allowance section and the end allowance section are provided in the driving allowance time interval, the operation S531 is performed if the operation mode of the electrical appliance is the start allowance mode and the end allowance mode. If the operation mode of the electric appliance is not the start allowance mode and the end allowance mode, it is preferable to control the start and end of the operation of the electric appliance through the step of determining whether the start allowance mode or the end allowance mode exists (S51). Do.

9 is another embodiment of the control method of the present invention. Hereinafter, another embodiment of the control method of the present invention will be described with reference to FIG. 9.

In this embodiment, as in the embodiments of FIGS. 7 and 8, the step of receiving power information is first performed (S100), and then it is determined whether the user has selected an operation mode for driving the electrical appliance (S300). .

When the operation mode selection signal generated by the user is generated, the control method according to the present invention provides a current time (operation mode selection time) at which the selection signal of the operation mode is generated in any of the electricity rate sections provided in the power information receiving step (S100). After determining whether it belongs to a section, it provides a control method of optimized electrical products for each section.

However, in some cases, even if the user selects the operation mode, the selected operation mode may be executed after the predetermined time has elapsed (in the case of reservation setting), so that the scheduled execution time of the selected operation mode receives the electricity rate data. It may be more desirable to control the electric product after determining (S500) which time period of the electric charge interval provided in step (S100). Hereinafter, for the convenience of description, the latter will be described.

The step S500 of determining the time period to which the scheduled execution time belongs is whether the electric charge of the scheduled execution time that can be determined from the power information exceeds a predetermined value (S, see FIG. 6) or is less than or equal to the predetermined value S. It can proceed by judging.

If it is determined that the scheduled execution time of the selected operation mode is the on-peak time period, the control method of the present invention determines whether the scheduled execution time is within the start allowable period (S54).

If the scheduled execution time is within the start allowable interval, the control method according to the present embodiment will execute the operation mode selected by the user (S900). Otherwise, start the operation mode selected by the user until the start allowable interval starts. I will not wait.

In this case, it is preferable that a notification step S541 of displaying time information, etc., at which the start allowable interval is started, is performed so that the user can recognize the reason why the operation of the electric product is not immediately started.

In this way, even in the on-peak time section where the demand for electric power is high and relatively expensive electricity is charged, the operation mode input to the electric product is executed because the start allowable section is provided at the end of the on-peak time section. This not only solves the problem to some extent but also satisfies the user's desire to operate the electrical appliance.

On the other hand, the control method of the present invention may further include a step (S55) of determining whether the operation mode selected by the user is the 'starting allowable mode' even when it is determined that the scheduled execution time is included in the start allowance section.

Here, the 'starting allowable mode' may be defined as an operation mode in which the expected power consumption or the expected electric charge is less than or equal to a predetermined reference value when the driving mode is executed in the starting allowable section.

That is, the control method of the present invention may execute the selected operation mode only when the selected operation mode is the start allowance mode even when the operation mode is input in the start allowance section of the on-peak time period (S900).

This is because when the operation mode provided in the electrical appliance is a mode in which a heating wire such as a heater is used intensively, since power consumption is large, there is a concern that the power demand may be concentrated.

On the other hand, in the control method of the present invention, if the scheduled execution time is not within the allowable start period, if the user is not in the start allowable mode, the user proceeds to the notification step S551 asking whether to execute the operation mode selected in the off-peak time interval (S551). The selected operation mode will be executed at will.

Hereinafter, a control method in the case where it is determined that the time interval to which the execution scheduled time point belongs is determined as the off peak time interval (S500) will be described.

If it is determined that the scheduled execution time belongs to the off-peak time period, the control method of the present invention determines whether the selected operation mode within the off-peak time period ends (S56), and if it is determined that the execution time ends in the off-peak time period, the selected operation is immediately performed. The mode is executed (S900).

However, if the operation mode within the off-peak time period is not terminated, the control method of the present invention determines whether the selected operation mode is terminated within the end allowable interval (S561).

If the selected operation mode is terminated within the end allowable interval, the selected operation mode is executed (S900). Otherwise, a notification step (S5611, next off-peak time interval) is asked whether or not to execute the remaining operation in the next off-peak period. Information can be displayed), and the remaining administration is executed according to the user's intention.

If the user selects to proceed with the remaining stroke in the next off-peak time period, the control method of the present invention executes the selected operation mode until the end of the off-peak time period (S565) and then starts the next off-peak time period (S567). When the remaining stroke is executed (S569).

On the other hand, the control method according to the present embodiment further determines whether the stroke executed in the end allowance section is the end allowance mode (S563) even when it is determined that the selected operation mode is terminated in the end allowance section (S561). It may include.

Here, the meaning of the 'end allowable mode' means that when the operating mode of the electric product is executed in the end allowable section of the on-peak time period, the expected power consumption or the expected electric charge is equal to or less than a predetermined reference value (standard power consumption or reference electric charge). It may be defined as an operation mode.

This is to prevent the increase in the power demand in the on-peak time period when the operation mode provided in the electrical appliance is a mode of intensively using a heating wire such as a heater.

Meanwhile, in the above-described embodiment, the driving allowable time section has been described only for the start allowable section, which is a time section including the end point of the on-peak time section, and the end allowable section including the start point of the on-peak time section.

However, the driving allowance time interval may be provided as a partial driving allowance interval provided between the start allowance section and the end allowance section. In this case, the partial driving allowance period may be defined as a time period that allows the driving of the electric product in a limited of the on-peak time period.

Suppose an electrical appliance is started in the allowable start period or in the off-peak period but ends in the next off-peak period.

In this case, the control method of the present invention avoids the on-peak time period because it can drive the electric product in the partial driving allowance period of the on-peak time period provided before the off-peak time period when the operation of the electrical appliance is finished. While driving the product, it is possible to minimize the running time delay of electrical appliances.

The present invention may be practiced in various forms and is not limited to the above-described embodiment. Therefore, if the modified embodiment includes the components of the claims of the present invention will be seen as belonging to the scope of the present invention.

10: power supply network 20: measuring device 30: energy management device

Claims (21)

(a) recognizing an on-peak time period in which at least one or more power information including an electric charge exceeds a predetermined value and an off-peak time period that is less than or equal to the predetermined value;
(b) determining whether a driving allowance time period of the electrical appliance exists in the on peak time period;
(c) controlling to include at least a part of the driving time of the electrical appliance in the driving allowable time interval. The method of claim 1,
The driving allowable time period is a control method for an electric product, characterized in that the time period during which the power consumption information value expected when the electric product is operated within the on-peak time period is less than a predetermined reference. The method of claim 2,
And the power consumption information value is any one of an electric charge, a power consumption amount, and an operation time. The method of claim 2,
The predetermined criterion may be any one of a predetermined ratio of a driving time set in the electrical appliance, a constant ratio of a power consumption amount, or a constant ratio of an electric charge. The method of claim 4, wherein
The predetermined criterion may be set by a user, or by a controller for controlling driving of an electric product using the power information, or by a power supply source providing the power information. The method of claim 2,
The predetermined criterion is a control method of an electrical appliance, characterized in that any one of the driving time, the electrical charge, or the amount of power consumption of the electrical appliance. The method of claim 6,
The predetermined criterion is set by the user, the control unit for controlling the operation of the electrical appliance is set using the power information, or the control method of the electrical appliance, characterized in that set by the power supply source providing the power information. The method of claim 2,
The driving allowance time period is characterized in that the start allowance period for starting the drive of the electrical appliance,
And the start allowable section includes an end point of the on-peak time section, but is a time section before the off-peak time section. The method of claim 8,
The predetermined criterion is a control method for an electrical appliance, characterized in that the time interval less than a predetermined ratio of the driving time set in the operation mode provided in the electrical appliance. 10. The method of claim 9,
And controlling the electric appliance only when the expected power consumption is less than a predetermined reference value when the operation mode is executed within the start allowable section. 10. The method of claim 9,
And controlling the electric appliance only when the expected electric charge is less than or equal to a predetermined reference value when the operation mode is executed within the start allowable section. The method of claim 8,
The predetermined criterion is a control method for an electric product, characterized in that the power consumption is expected to be less than a predetermined reference value when the operation mode provided in the electric product in the on-peak time period. The method of claim 8,
The predetermined criterion is a control method for an electric product, characterized in that when the operation mode provided in the electric product is executed in the on-peak time period, the expected electric charge is a time interval less than a predetermined reference value. The method of claim 2,
The driving allowable time period is characterized in that the end allowable interval for the end of the drive of the electrical appliance,
And the end allowable section includes a start point of the on-peak time section but is a time section after the off-peak time section. The method of claim 14,
The end allowable section is a control method for an electrical appliance, characterized in that the time interval less than a predetermined ratio of the driving time set in the operation mode provided in the electrical appliance. 16. The method of claim 15,
And controlling the electric appliance only when the expected power consumption is less than a predetermined reference value when the operation mode is executed within the end allowable section. 16. The method of claim 15,
And controlling the electric appliance only when the expected electric charge is less than or equal to a predetermined reference value when the operation mode is executed within the end allowable section. The method of claim 14,
The end allowable period is a control method for an electric product, characterized in that the power consumption is expected to be set to the predetermined time period or less when the operation mode provided in the electric product in the on-peak time period. The method of claim 2,
The driving allowable time period includes a start allowable period in which driving of the electric appliance is started and an end allowable period in which driving of the electric appliance is terminated.
The driving allowable time interval is a sum of power consumption information value expected when the electrical appliance is driven in the start allowable interval and power consumption information value expected when the electrical appliance is driven in the end allowable interval is less than or equal to the predetermined criterion. The control method of the electrical appliance, characterized in that the time interval. The method of claim 1,
Recognizing the on-peak time period and the off-peak time period is
Is recognized by comparing the power information provided to the electrical appliance with the predetermined value set in the electrical appliance, or
The control method of the electrical appliance, characterized in that it is recognized by the information of the on-peak time period and the off-peak time interval provided from the outside of the electrical appliance. The method of claim 2,
The driving allowance time period is characterized in that the partial drive allowance period for maintaining the drive of the electrical appliance for a predetermined time,
And the partial driving allowance section is a time section provided between a start allowance section including a start point of the on-peak time section and an end allowance section including an end point of the on-peak time section.

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