KR20140029064A - A home appliance - Google Patents

Abstract

A home appliance according to an embodiment of the present invention comprises: a driving unit operated based on the power information including information on electricity prices; a communication module requesting the power information to an external component; a memory unit in where the power information received via the communication module is stored; and a control unit for controlling the communication module to receive a second power information excluding a first power information after receiving the first power information corresponding to the current time among the power information. [Reference numerals] (AA) Start; (BB) End; (S21) Complete the communication link between a first component and a second component; (S22) Perform time synchronization between the first component and the second component; (S23) Request the first power information from the first component to the second component; (S24) Receive the first power information from the second component and transmit a check signal of the first component; (S25) Store the first power information of a volatile memory; (S26) Request the second power information from the first component to the second component; (S27) Receive the second power information from the second component and transmit the check signal of the first component; (S28) Store the second power information in the volatile memory; (S29) Receive a power information transmission completion signal from the second component; (S30) Complete the power information transmission between the first component and the second component

Description

Electrical Appliances {A home appliance}

The present invention relates to an electrical product.

BACKGROUND ART [0002] Generally, home appliances include a washing machine, a refrigerator, a cooking appliance, or a vacuum cleaner. Conventionally, the electric appliance has been driven using electric power having constant power information. For example, the electricity charges supplied to the home were constantly formed over time.

However, in recent years, in conjunction with the energy saving policy, it has become possible to supply power having power information that varies with time.

However, in order to drive an electric product based on the fluctuating power information, a user must separately check the electric power information through the Internet, etc., and determine the operation time or the operating course of the electric product based on the confirmed contents. There was a ham.

In particular, the user often wants to check the power information corresponding to the current time, the power information is provided only for a predetermined period, for example daily, weekly or monthly, so that the user can drive the electrical appliance (time, course Etc.) had to be calculated manually.

For example, based on the operation information provided for each cycle, there is a problem in that the user intuitively determines the operation start time, operation end time, or operation course of the electrical appliance.

In order to solve this problem, the present embodiment has an object to provide an electric product that can easily receive power information from the outside.

The electrical appliance according to the present embodiment includes a driving unit operated based on power information including information on a power charge; A communication module for requesting the power information from an external component; A memory unit for storing the power information received through the communication module; After receiving the first power information corresponding to the current time of the power information, the control unit for controlling the communication module to receive the second power information except the first power information is included.

According to the proposed embodiment, the electrical appliance receives power information from an external component and has an advantage of performing driving to reduce cost based on the received power information.

In addition, since the electrical appliance can separately receive the first power information corresponding to the current time and the second power information corresponding to the current time after the external component, whether the electrical appliance is advantageous to operate at the current time. There is an advantage that can be effectively recognized.

In addition, the user can easily determine whether to operate the current time based on the first power information corresponding to the current time.

In addition, when the power of the electrical appliance is turned on and connected to the external component, since the power information can be received from the external component, there is an advantage that the new power information can be updated to the electrical product.

In addition, since the electrical appliance can request and receive the power information again before and after the time when the power information is changed, and compare it with the previously stored power information, there is an advantage that the verification of the accuracy of the power information can be effectively performed.

Further, after receiving the first power information, when receiving and requesting the second power information, the first power information may be received together to determine whether the first power information is changed. There is an advantage that verification of accuracy can be made.

1 is a view showing an electrical product and external components according to a first embodiment of the present invention.
2 is a block diagram showing the configuration of an electrical product and an external component according to the first embodiment of the present invention.
3 is a flowchart illustrating a communication connection process between a plurality of components according to a first embodiment of the present invention.
4 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to the first embodiment of the present invention.
5 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to a second embodiment of the present invention.
6 is a graph showing a request form of power information according to a third embodiment of the present invention.
7 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to a fourth embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

1 is a view showing an electrical appliance and an external component according to a first embodiment of the present invention, Figure 2 is a block diagram showing the configuration of the electrical appliance and external components according to a first embodiment of the present invention.

1 and 2, the network system 10 according to the first embodiment of the present invention includes an electrical appliance 100 that performs a predetermined function as a component constituting the network system 10, and As another component constituting the network system 10, an external component 200 provided to communicate with the electrical appliance 100 is included.

The electrical appliance 100 includes a driving unit 170 that is driven to perform the function of the electrical appliance. The driving unit 170 may be driven based on information on energy supplied from the outside. The information on the energy includes information related to the energy charge.

For example, the information related to the energy bill may include a power bill, and the driving unit 170 may be driven at a time or manner in which the power bill may be reduced during the driving of the electrical appliance 100. .

The external component 200 can be understood as a component that provides information to the electrical product 100 about energy supplied from an external energy source. Here, the external energy source may be at least one of an energy generation unit (electric power company), an energy distribution unit (electric power distribution company), and an energy storage unit (energy storage / supply company).

For example, the external component may include a smart meter capable of monitoring the electricity consumption of the electric appliance, an AMI (Advanced Metering Infrastructure) measuring the electricity consumption of a plurality of electric appliances or consumers, And an energy management system (EMS: Energy Management System) for controlling the power saving operation of the electric product.

1 shows a washing machine as an example of an electric appliance. However, there is no restriction on the type of electrical appliances, and a refrigerator, a cooking appliance, a dryer, an air conditioner, a cleaner or a water purifier may be applied in addition to the washing machine.

The electrical appliance 100 includes a first communication unit 110 for enabling the electrical appliance 100 to be communicatively connected to the external component 200 and a display unit for displaying an operating state of the electrical appliance 100. 120 and a first input unit 130 for inputting a predetermined command for the operation of the electrical appliance 100 is included.

In addition, the electrical appliance 100 includes a memory unit 140 for storing operation information of the electrical appliance 100 or information on energy supplied to the electrical appliance (hereinafter referred to as energy information) and for controlling the configuration thereof. The product control unit 150 is further included. For example, the energy information may be power information. Hereinafter, the case where the energy is electric power will be described as an example.

The first communication unit 110 may be understood as a gateway connected to the external component 200. In addition, the first communication unit 110 may be provided as a “communication module” inside the front panel 105 of the electrical appliance 100. However, the first communication unit 110 may not be embedded in the electrical appliance 100, but may be provided outside.

The first communication unit 110 receives external information according to a control command of the product control unit 150 and transmits the external information to the product control unit 150 or transmits internal information of the electrical appliance 100 to an external (for example, an external component). (200).

The memory unit 140 may be disposed separately from the first communication unit 110 or may be provided as a memory disposed in the communication module when the first communication unit 110 is provided as a module.

In addition, a second interface 170 for transmitting and receiving information (data) may be defined between the first communication unit 110 and the product control unit 150.

The external component 200 may include a second communication unit 210 communicatively connected to the first communication unit 110, a display unit 220 displaying a user interface of the external component 200, and the external component. The second input unit 230 for inputting a predetermined command to the 200 is included.

In addition, the external component 200 includes a memory unit 240 for storing operation information of the electrical appliance 100 and a controller 250 for controlling these components. Here, the operation information of the electrical appliance 100 may include power usage information of the electrical appliance.

The second communication unit 210 may transmit the power information to the first communication unit 110, and may receive the operation information of the electrical appliance 100 from the first communication unit 110. A first interface 300 for communication may be defined between the first communication unit 110 and the second communication unit 210.

The display unit 220 may display operation information of the electrical product 100 or power information provided to the electrical product 100.

The memory unit 240 may store a plurality of pieces of information for performing the functions of the external component 200. The plurality of pieces of information includes first information on electric power supplied to the electric product (100) and second information on operation or power consumption of the electric product (100).

3 is a flowchart illustrating a communication connection process between a plurality of components according to a first embodiment of the present invention.

3 shows a process in which communication is connected between a plurality of components constituting the network system 10 according to the first embodiment of the present invention. In one example, communication for transmitting and receiving information between the first component and the second component can be started.

Here, the first component may be the electrical appliance 100, and the second component may be the external component 200.

When the power of the first component is turned on, the first component recognizes its own unique device code (device code) and the IP (communication address) of the first communication unit 110 is recognized. Can be assigned.

The self code may be a unique identification number (letter) given at the time of manufacture, installation or sale of the first component. When the power of the first component is turned on, information related to the own code may be transmitted to the first communication unit 110.

The IP may be set to a fixed IP or a floating (floating) IP for communication with the second component. In addition, the IP may be allocated through a separate access point (AP) according to a communication method, or may be allocated by self setting of the first component. For example, the communication method may include Wi-Fi, Bluetooth, or Zigbee.

Similarly, when the power of the second component is turned on, the second component is recognized with its own device code (second code), and the IP of the second communication unit 210 is allocated. It may be (S11, S12).

In order to connect the communication between the first component and the second component, a predetermined command may be input to the first component or the second component. For example, a predetermined command may be input to the first component. The predetermined command may be automatically recognized by manipulating a preset input unit or after the power of the first component is turned on.

When the predetermined command is input, a connection signal for connection with a second component is generated in the first component. The connection signal of the first component may be received by the second component (S14).

The information of the first component and the information of the second component may be interchanged. Information exchanged between the first component and the second component may include the IP address of each component and its own code information.

The information may be directly exchanged by recognizing or searching for a counterpart component (device) by the first component or the second component, or via a specific server that stores information of the first component or the second component. It may be exchanged (S15).

As the information of the first component and the second component are exchanged with each other, the first and second components may be communicatively connected. When the first and second components are connected in communication, information (data) transmission and reception between them is possible (S16).

4 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to the first embodiment of the present invention.

When the communication connection between the first and second components described with reference to FIG. 3 is completed (S21), a time synchronization process is performed between the first and second components. The time synchronization process will be described briefly.

The electrical appliance may determine an operating time or operation method of the electrical appliance based on the power information. In this case, the power information may include time information and fee information. In one example, the electrical appliance may be controlled to be driven at a low time period.

To this end, the time information included in the power information is required to be reflected in the first component or the second component, and the process of matching the time information between the first and second components may be understood as "time synchronization". Can be.

If time information of the second component, that is, time information included in power information and time information of the first component are different, operation control of the component may be performed in an undesired direction. For example, in a situation where the power bill is expensive, there may be a problem that the components constituting the electrical appliance are operated.

Accordingly, first time information transmitted from the second component and second time information included in the first component may be compared.

If the first time information is identical to the second time information, it can be determined or confirmed that the time synchronization is performed. On the other hand, if it is recognized that the first time information is not the same as the second time information, the second time information of the first component is changed to the first time information.

The synchronization status check or synchronized result signal may be transmitted to the second component. As described above, since the time information of the first component is the same as the time information included in the power information, the control of the component based on the power information can be easily performed (S22).

When time synchronization is performed, the first component 100 requests first power information corresponding to a current time from the second component 200. Here, the first power information corresponding to the current time is understood as power information applied when it is assumed that the electric product is currently driven.

In general, since the user is most interested in the power bill generated when the electrical appliance is immediately driven immediately, the first component 100 first requests the first power information (S23).

The second component 200 transmits the first power information of the power information to the first component 100, the first component 100 after receiving the first power information, the second component The acknowledgment signal is transmitted as a signal received well at 200 (S24).

The first power information received by the first component 100 may be stored in the memory unit 140. In the present embodiment, the memory unit 140 may be a volatile memory in which the stored information is lost when the electrical appliance 100 is turned off.

Therefore, the information stored in the memory unit 140 is lost when the power of the electrical appliance 100 is turned off, and when the power of the electrical appliance 100 is turned on, the memory unit 140 is the second component. Power information may be newly received and stored from 200 (S25).

After receiving the first power information, the first component 100 requests the second component 200 for the second power information. The second power information is power information excluding the first power information among the power information, and may be understood as power information corresponding to a time zone after a current time (S26).

When the first component 100 receives the second power information from the second component 200, the first component 100 may transmit a confirmation signal to the second component 200. The received second power information may be stored in the memory unit 140 (S27, S28).

In the process of transmitting and receiving the second power information, the first power information previously transmitted and received may be transmitted together. Therefore, it is possible to verify whether a change occurs in the first power information during the transmission and reception of the second power information.

Meanwhile, a process of transmitting and receiving the first power information and the second power information may be performed a plurality of times. In particular, when the capacity of the power information to be transmitted and received is large, the transmission and reception of the first power information or the second power information may be performed a plurality of times.

In addition, whether the transmission and reception of the power information is completed may be determined according to whether a power information transmission completion signal is received from the second component 200. After the transmission and reception of the second power information is performed at least once, when the power information transmission completion signal of the second component 200 is received by the first component 100, Transmission and reception may be completed (S29, S30).

The first power information or the second power information may include cost ID information, a start time to which a cost is applied, and a duration of the corresponding cost. Here, the cost is understood as a power rate.

The cost classification information may include names that can distinguish the costs, such as the first cost, the second cost, and the third cost. The cost application start time represents a start point at which the first cost, the second cost, or the third cost is applied, and the cost duration is a time interval in which the first cost, the second cost, or the third cost lasts. Can be represented.

For example, the first cost has a start time (12:00 PM) and a duration (3 hours 30 minutes), and the second cost has a start time (15:30 PM) and a duration (5 hours), and 3 Costs can have a start time (20:30 PM) and a duration (4 hours 30 minutes).

The first power information or the second power information may be tabled and transmitted to the first component 100.

When the first and second power information is transmitted to the electrical appliance 100, the electrical appliance 100 performs a power saving drive based on the first and second power information so that a power charge can be reduced, or the user I can recommend work driving method about power saving drive.

5 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to a second embodiment of the present invention.

When the communication connection between the first and second components is completed, time synchronization is performed. The first component 100 requests first power information from the second component 200, and when receiving the first power information from the second component 200, identifies the second component 200. The signal is transmitted (S31 to S34).

The first component 100 compares the received first power information with previously stored power information stored in the memory unit 140. In the present embodiment, the memory unit 140 may be a nonvolatile memory capable of maintaining information storage even when the electrical appliance 100 is powered off.

That is, after the first component 100 is powered on and receives the first power information from the second component 200, the power information and the first power information previously stored in the memory unit 140 It may be compared (S35).

If the received first power information and the pre-stored power information is the same (S36), as a subsequent step, the first component 100 requests and receives the second power information from the second component 200, and confirms Signals can be transmitted (S38, S39).

On the other hand, if the received first power information and the pre-stored power information is not the same (S36), the received first power information is stored in the memory unit 140. That is, the power information stored in the memory unit 140 is changed or updated with the first power information. In addition, the steps S38 and S39 may be performed (S37).

The first component 100 compares the received second power information with previously stored power information stored in the memory 140 (S40).

When the received second power information and the pre-stored power information is the same (S41), the process of transmitting and receiving the second power information is performed until the transmission completion signal of power information is received from the second component 200, When the transmission completion signal is received, transmission and reception of power information between the first and second components 100 and 200 may be completed (S43 and S44).

On the other hand, if the received second power information and the pre-stored power information is not the same (S41), the received second power information is stored in the memory unit 140. That is, the power information stored in the memory unit 140 is changed or updated with the first power information. In addition, the steps S43 and S44 may be performed (S42).

6 is a graph showing a request form of power information according to a third embodiment of the present invention.

6 shows a change in power information, that is, power cost over time. The illustrated contents are briefly described.

The X-axis value represents the time elapsed from the present time T0 to the starting point, and the Y-axis value represents the power cost.

The first power information corresponding to the current time T0 may be defined as cost classification information (first cost P1), a start time T0, and a duration T1 -T0.

Second power information other than the first power information, that is, power information corresponding to a time zone after the current time T0 may include the following detailed power information table.

1. Cost breakdown information (second cost (P2)), start time (T1) and duration (T2-T1).

2. Cost breakdown information (third cost (P3)), start time (T2) and duration (T3-T2).

3. Cost breakdown information (fourth cost (P4)), start time (T3) and duration (T4-T3).

In this manner, the power information exists many times when the cost is changed. In detail, the cost is varied in T1, T2, and T3.

When the supplied power cost is changed, the change point (hereinafter, referred to as cost change point) may be an important factor in controlling the operation of the electrical appliance 100. Therefore, in the present embodiment, the first component, that is, the electrical appliance 100 may request power information from the second component 200 at the time point of the cost change.

That is, the electrical appliance 100 may request power information at the boundary points of (A), (B), and (C) shown in FIG. 6. For example, the time when the electrical appliance requests power information may be a boundary time of (A), (B), (C), may be earlier than the boundary time by a set time, and from the boundary time It may be as long as the set time.

As described above, the electrical appliance 100 may verify whether the power information is the same as previously stored power information by requesting the power information again before or after the boundary time at which the cost information included in the power information changes, or before and after.

As a result, since the electrical appliance 100 can be operated and controlled based on accurate power information, there is an effect that the user can be prevented from operating the electrical appliance in an undesired cost section due to wrong power information.

7 is a flowchart illustrating a process of transmitting and receiving power information between a plurality of components according to a fourth embodiment of the present invention.

An embodiment in which the first component is controlled to periodically check power information will be described with reference to FIG. 7.

In detail, when the power of the first and second components 100 and 200 is turned on and the communication connection is completed, the first component 100 requests power information from the second component 200. When power information is received from the second component 200, the first component 100 stores power information and transmits a confirmation signal to the second component 200 (S51 to S54).

When the set time elapses (S55), the first component 100 may request and receive power information from the second component 200 again.

In addition, it may be recognized whether there is a change in the newly received power information, and if there is a change, the changed power information is stored in the memory unit 140 of the first component 100 (S56 and S57). On the other hand, if there is no change in the power information, the process of S55 or less is repeated. Here, the change of the power information may be any one of the power cost, start time, and duration.

The processes of S55 to S57 may be performed until the OFF command for the power supply of the first component 100 or the second component 200 is recognized (S58, S59).

As such, the request and reception of the power information is performed according to a setting cycle, so that the electric product can periodically update the correct power information.

Other embodiments are suggested.

In the first and second embodiments, the request of the second power information is made after the first component requests and receives the first power information and the acknowledgment signal is transmitted to the second component (sequentially). Transmission and reception).

Alternatively, the first power information and the second power information may be controlled to transmit and receive the second power information immediately after the transmission and reception of the first power information, without a separate process such as request, reception and confirmation signal transmission. (One-way transmit and receive). When the transmission and reception of the second power information is completed, the second component may transmit a transmission completion signal of power information to the first component.

Another embodiment is proposed.

The third embodiment requests power information at a point in time when there is a change in cost among the power information, and the fourth embodiment periodically requests power information.

On the contrary, when there is a change in at least some of the power information, that is, the power cost, start time, or duration, the second component transmits the changed power information to the first component without the request of the first component. You could do it.

100: electrical product 110: first communication unit
120: display unit 130: first input unit
140: memory unit 150: product control unit
200: external component 210: second communication unit

Claims (17)

A driving unit operated based on the energy information including information on the energy fee;
A communication module for requesting the energy information from an external component;
A memory unit for storing the energy information received through the communication module;
And a controller configured to control the communication module to receive second energy information except for the first energy information after receiving first energy information corresponding to a current time of the energy information. The method of claim 1,
The communication module includes:
And requesting the energy information from the external component when the power supply of the electrical appliance is turned on. The method of claim 1,
The memory unit,
And the volatile memory for losing the energy information when the electrical appliance is turned off. The method of claim 3, wherein
The memory unit,
And when the electrical appliance is turned on, storing the new energy information received by the communication module. The method of claim 1,
The memory unit,
And a non-volatile memory for maintaining the storage state of the energy information even when the electrical appliance is turned off. The method of claim 5, wherein
The memory unit,
When the electrical appliance is turned on, the electrical appliance, characterized in that for changing the energy information previously stored in the memory unit to the energy information received by the communication module for storing. The method of claim 1,
The memory unit,
An electric product, characterized in that the module memory disposed in the communication module, or a memory provided separately in addition to the communication module. The method of claim 1,
And the first energy information and the second energy information are sequentially or unilaterally received. The method of claim 1,
In the process of receiving the first and second energy information sequentially,
The communication module requests and receives the first energy information and transmits an acknowledgment signal to the external component.
And requesting and receiving the second energy information. The method of claim 9,
The communication module includes:
And when the reception of the second energy information is completed, a transmission completion signal is received from the external component. The method of claim 9,
The communication module includes:
And receiving the first energy information together when receiving the second energy information, thereby checking whether the first energy information is changed. The method of claim 8,
In the unilateral reception of the first and second energy information,
The communication module includes:
And receiving the second energy information without transmitting an acknowledgment signal after receiving the first energy information. The method of claim 1,
If the information on the energy bill is changed,
And the communication module requests energy information from the external component before or after the energy charge is changed. The method of claim 1,
The communication module includes:
Periodically request energy information from the external component,
The electrical appliance, characterized in that for confirming whether or not the change of the energy information. The method of claim 1,
When a change occurs in the energy information, the communication module,
Electrical appliances, characterized in that for receiving the changed energy information from the external component without a separate request. The method of claim 1,
In the first energy information or the second energy information,
An electric product, characterized in that the energy rate classification information, the start time for applying the energy rate and the duration of the energy rate are transmitted or received in a table. The method of claim 1,
The external component is an electrical appliance that is a smart meter that grasps the amount of energy used by the electrical appliance and transmits charge information on the electrical appliance to the electrical appliance.

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