KR101853661B1 - Electronic device and method of controlling power supply in the same - Google Patents

Abstract

An electronic apparatus according to the present invention includes an external power supply unit that receives external power, an auxiliary power storage unit that receives power from the external power supply unit for charging and storing, an external power supply unit, and an auxiliary power storage unit. A first switching unit for selecting one of the first switching unit and the second switching unit, and a power switching unit for switching the first switching unit, the second switching unit, and the second switching unit based on power information received from the power information receiving unit, And a control unit for controlling the unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electronic device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power control method for an electronic apparatus and an electronic apparatus, and more particularly, to an electronic apparatus that provides an efficient power selection method using power information and a power control method thereof.

In recent years, interest in green energy and technology has been increasing all over the world, and Smart Grid technology for responding to energy environmental problems is becoming an important environmental technology.

The Smart Grid is a next-generation power network that can optimize energy efficiency by configuring the power supply network and the power supply network so that the power supplier and the consumer can exchange and control real-time information in both directions.

Therefore, there is a need to embed an effective smart grid function in each electronic device, and actual demonstration projects are being conducted locally at home and abroad.

On the other hand, Fig. 1 shows an example of power use in a general electronic apparatus. The electronic devices 10 and 20 include a battery detachable module such that the batteries 11 and 21 are integrally contained in the device or the detachable battery is possible. Particularly, among the electronic devices, the products including the battery are widely used in portable electronic devices (for example, notebooks, smart phones, personal information terminals, etc.).

In a conventional electronic device, when the external power source 12 or 22, which may be an 'AC power source' or a 'system power source', is connected, ). Generally, the external power source is a power source provided by a power supply company, and charges for usage are charged. Further, when there is no connection to the external power source, the internal batteries 11 and 21 are used as the used power source. That is, in the conventional electronic apparatus, the external power is always used as the used power without using the battery when the external power is connected, and the external power is always used as the battery charging power when the external power is connected.

Recently, the development of a new power grid combining digital technology with a conventional analog grid is being discussed. The new digital power network is under development for a method of transmitting and receiving power information in real time via two-way communication through fusion with information and communication technology. For example, the Smart Grid technology, widely referred to as the intelligent power grid, is one of the power grid technologies under development. Hereinafter, 'smart grid power information network', 'smart grid', or 'power network' referred to in the present invention refers to an example of an intelligent power grid capable of bidirectional communication. For convenience of explanation, the intelligent power network will be referred to as a 'smart grid power information network'. The smart grid power information network can be implemented in various ways, for example, through a widely used Internet network or power line communication (PLC), or a new power information network can be standardized and implemented It will be possible.

As the discussion on the smart grid power information network becomes more active, there is a growing demand for reduction of electricity usage in electronic devices. Particularly, discussions on reduction of electricity use through efficient power selection are also included. Therefore, when the external power source is connected as in the conventional method, the method of using only the external power source unconditionally or always charging the battery using the external power source without considering the battery charging state causes unnecessary power use , There arises a problem of imposing an economic burden on the user.

It is an object of the present invention to provide an efficient power control method using power information and an electronic apparatus to which such a power control method is applied.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise forms disclosed. Other objects, which will be apparent to those skilled in the art, It will be possible.

According to an aspect of the present invention, there is provided an electronic apparatus including an external power supply unit supplied with external power, an auxiliary power storage unit receiving power from the external power supply unit for charging and storing, an external power supply unit and an auxiliary power storage unit, And an auxiliary power storage unit, a first switching unit configured to select one of the power saving unit and the auxiliary power storage unit as a used power source, a power information receiving unit to receive power information including at least one of power charge information or power demand information, And a control unit for controlling the first switching unit based on the information.

The controller may control the first switching unit to determine the high charge period of the power charge information or the high demand period of the power demand information as the power saving time period and to select the auxiliary power storage unit as the power source during the power saving time period.

The electronic device may further include a second switching unit for selecting whether to charge the auxiliary power storage unit by the external power supply, and the control unit may control the second switching unit to block the charging of the auxiliary power storage unit during the period determined as the power saving time period .

And an auxiliary power detecting unit for detecting an amount of auxiliary power charged in the auxiliary power storage unit and outputting information on the auxiliary power amount to the control unit.

The controller may control the second switching unit to charge the auxiliary power storage unit with external power when the auxiliary power detected by the auxiliary power detection unit is less than the reference value and is not the power saving time period.

The control unit may control the first switching unit to select the external power source as the used power source when the auxiliary power amount detected by the auxiliary power amount sensing unit is equal to or lower than the reference value.

An AC power input unit for receiving an AC power supplied from an external AC power source and supplying the AC power to an external power unit, a DC power input unit for receiving a DC power supplied from an external DC power storage unit and supplying the DC power to an external power unit, And a third switching unit connected to the third switching unit to select one of the AC power and the DC power as the used power, and the controller controls the third switching unit to select one of the AC power and the DC power based on the power information Can be controlled.

The control unit may determine the overcharge period of the high-rate charging period or the power demand information of the power charge information as the power saving period, and may control the third switching unit to select the DC power source as the power source during the power saving period.

The control unit may control the third switching unit to select the AC power source as the used power source when the DC power amount stored in the external DC power storage device is equal to or lower than the reference value.

According to another aspect of the present invention, there is provided a power control method for an electronic apparatus, the power control method comprising: receiving power information including at least one of power charge information and power demand information; And an auxiliary power storage unit for receiving power from the power supply unit and the external power supply unit to charge and store the selected auxiliary power storage unit.

At this time, the step of selecting may include a step of determining a high-charge period of the electric power charge information or an overhead period of the electric power demand information as the power saving time period, and a step of selecting the auxiliary power storage as the power source during the power saving time period.

The power control method of the electronic device may further include blocking the charging of the auxiliary power storage unit in a period determined as the power saving time period.

The method of controlling a power supply of an electronic device includes the steps of sensing an amount of auxiliary power charged in an auxiliary power storage unit and charging the auxiliary power storage unit with an external power supply when the detected auxiliary power amount is less than a reference value and is not a power saving time period .

The power control method of an electronic device may include detecting an amount of auxiliary power charged in the auxiliary power storage unit and selecting an external power source as the used power when the detected auxiliary power amount is less than a reference value.

In the selecting step, the external power supply may be one of an AC power supply and a DC power supply supplied from an external DC power storage device, and may be configured to select one of an AC power supply and a DC power supply as a power supply based on the power information .

The power control method of the electronic apparatus may further include a step of determining a high-charge period of the power charge information or an overhead period of the power demand information as a power saving time period, and a step of selecting a DC power source as the power source during the power saving time period.

At this time, when the DC power stored in the external DC power storage device is lower than the reference value, the AC power can be selected as the used power.

As a result, it is possible to select a power source suitable for reducing power consumption and prevent unnecessary battery charging through various embodiments of the present invention, thereby enabling economical and efficient use of power when utilizing electronic devices.

Fig. 1 shows an example of power use in a conventional general electronic device.
2 is a schematic diagram illustrating power usage using a smart grid power information network according to a first embodiment of the present invention.
3 is a block diagram showing an electronic apparatus according to the first embodiment of the present invention.
4 is a flowchart showing a first example of a power supply control method in an electronic apparatus according to the first embodiment of the present invention.
5 is a flowchart showing a second example of the power supply control method in the electronic apparatus according to the first embodiment of the present invention.
6A to 6D are schematic views illustrating a message screen provided to a user in the electronic device according to the first embodiment of the present invention.
7A is a block diagram showing an electronic apparatus according to a second embodiment of the present invention.
FIG. 7B is a flowchart showing a power supply control method in the electronic device according to the second embodiment of the present invention.
8A is a block diagram showing an electronic apparatus according to a third embodiment of the present invention.
8B is a flowchart showing a power supply control method in an electronic device according to the third embodiment of the present invention.
9A is a block diagram showing an electronic apparatus according to a fourth embodiment of the present invention.
9B is a flowchart showing a power supply control method in an electronic apparatus according to a fourth embodiment of the present invention.
10A and 10B are schematic views illustrating a message screen provided to a user in an electronic device according to a fourth embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described. It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

FIG. 2 is a whole conceptual diagram to which an electronic device according to an embodiment of the present invention is applied, illustrating use of a power source using a smart grid power information network.

Various smart grid participants are connected to the smart grid power information network 100 and the network 200 (the 'home network' or the 'building network') in the reception building is connected to the smart grid power information network 100). Similarly, the network 200 can be configured as a wired or wireless communication network. However, the network 200 and the smart grid power information network 100 are only for convenience of explanation, and the network 200 may be widely understood as a part of the smart grid power information network 100. [

In addition, a variety of devices are connected to the inside of the reception building through the network 200. For example, the smart grid power information network 100 receives smart power information, A server 201 (Smart Server), and electronic appliances 202 to 207 (also referred to as " Smart Appliances ") that require power use.

Accordingly, the power usage control of the electronic devices 202 to 207 can be performed through the device itself, but it is designed to have a structure capable of controlling devices according to control commands by the smart server 201 through the network 200 It is possible. This will be described in detail later.

The smart server 201 may be a separate product, but it is also possible that one of the electronic devices 202 to 207 performs the function of a smart server. For example, it is possible to replace the smart TV 204 or the personal computer 206 or the portable personal terminal 207 having a display function with the smart server 201 and utilize it.

The present invention relates to an efficient power control method in a product using an auxiliary power storage unit (for example, a battery) among various electronic apparatuses connected to the smart grid power supply information network 100 through the internal network 200 I want to explain. The product utilizing the auxiliary power storage unit (for example, battery) may be, for example, a personal computer 206 or a portable personal terminal 207, It is common to have batteries 206a and 207a therein. However, the present embodiment is not limited to the personal computer 206 or the portable personal terminal 207. For example, the fixed personal computer 206 may be a smart server 201 (although portable is also possible), a water purifier 202, (For example, a battery) may be provided in the refrigerator 203, the smart TV 204, and the washing machine 205, or an external auxiliary power (for example, a home battery or an external device Battery) that can be used in connection with any product that would be applicable.

FIG. 3 shows an electronic device 400 according to the first embodiment of the present invention. The electronic device 400 according to the first embodiment of the present invention includes an external power supply unit 401, an auxiliary power storage unit 402 (for example, a battery), a charging circuit unit 403, a discharge circuit unit 404, A control unit 406, a power information receiving unit 407, a display unit 408, a first switching unit 409, and a second switching unit 410. The sensing unit 405, the control unit 406, the power information receiving unit 407,

However, the above-described configuration is shown as functional blocks for convenience of explanation. In actual implementation, the configuration may exist in a single configuration or may be implemented by a software program. Further, in a specific embodiment of the present invention, some of the above-described components may be additional components that are not necessarily required components.

The external power supply unit 401 receives power from an external power source (for example, 'electric power company' or 'micro grid') and supplies power to the device. However, the external power source may be the self-generated power generated by self-generated electricity (for example, solar energy, wind energy, etc.) in the consumer as well as the electric power provided by the external electric power company charged with electricity.

The auxiliary power storage unit 402 charges and stores electric power through the charging circuit unit 403, and supplies power to the device through the discharging circuit unit 404. The auxiliary power amount sensing unit 405 confirms the amount of available power or the amount of electric power charged in the auxiliary power storage unit 402, and transmits the amount of power or power to the control unit 406.

The power information receiving unit 407 receives the power information through the smart grid power information network 100 or the internal network 200. [ However, depending on the embodiment, the power information may be a power control command received from an external control device (e.g., smart server 201). In addition, the power information may be provided in real time or periodically provided on a predetermined time unit basis. Also, the type of the power information may be at least either the electric power rate information or the electric power demand information. Depending on the design, it is possible to include both the electric power rate information and the electric power demand information. In addition, the power information receiving unit 407 can receive the self power generation information. The self-generated information may include information that indicates whether the self-generated amount information in the customer, available surplus self-generated power amount information, and the current power supplied to the external power source are self-generated power.

Specifically, for example, the electric power rate information refers to information on the electric power rate that can be changed in real time or periodically, and includes information on the electric power rate per use electric power in a certain time unit. Accordingly, when the electric power charge information is received, the electric power charge in the current time zone can be confirmed, and it is possible to classify the electric power charge according to the setting criteria into a high-cost charging section or a low-cost charging section. For example, a power-providing company directs electricity charges at a point in time when electricity demand is high (referred to as "peak time") to a high-rate charge, thereby reducing the user's electricity use. On the other hand, the electric power charge at the time of low electricity demand is set as a low cost charge, thereby inducing the user to use electricity in the low charge time zone to avoid the high cost charge period.

In addition, the power demand information refers to information on power demand varying in real time or periodically, and it is possible to analyze the previous power use sun of each customer through the smart grid power information network 100, And it is calculated based on the received power amount information. Accordingly, when the electric power demand information is received, the electric power demand in the current time zone can be confirmed, and it can be classified into an over demand period or a low demand period according to a setting standard. For example, in an electricity demanding high demand period, the user is guided to reduce electricity usage by setting a high electricity rate or by imposing a separate incentive or penalty regardless of the electricity rate.

Therefore, the control unit 406 determines the power saving time zone from the power information received by the power information receiving unit 407 and determines the selection of the power source corresponding thereto. For example, the power saving time period can be determined as a high power billing interval or a power saving period as a power saving time zone, and it is possible to freely set whether a specific interval is a high billing interval or a demanding interval, by a user or a system.

The first switching unit 409 is designed such that it can select whether the external power source is to be used as a power source for the apparatus under the control of the control unit 406. The second switching unit 410 is connected to the control unit 406, The external power source is designed to be capable of selecting whether or not the external power source is charged into the auxiliary power storage unit 402 (for example, 'battery').

In addition to the display function inherent to the device itself, the display unit 408 performs a function of providing a message to the user on power selection and battery charging according to the operation of the control unit 406. [

Hereinafter, the first embodiment of the present invention will be described in detail with reference to Figs. 4 to 6D. 4 is a flowchart showing an example of a power supply control method in an electronic device according to the first embodiment of the present invention.

The power information receiving unit 407 receives the power information through the smart grid power information network 100 or the internal network 200 (S101). The control unit 406 determines whether the current time is the power saving time zone from the received power information (S102). As described above, the power saving time period may correspond to, for example, a case where it is judged from the electric power charge information to be a high-cost charging interval or from the power demand information to the excessive demand period.

If it is determined by the control unit 406 that the current time is not the power saving time period, the controller 406 checks the current amount of the battery 402 through the auxiliary power amount sensing unit 405 (S103). That is, if the remaining capacity of the battery is insufficient, the control unit 406 controls the first switching unit 409 to use an external power source and permits charging of the battery through the second switching unit 410 (S104). On the other hand, if the controller 406 does not correspond to the power save time, but the battery remaining amount is sufficient, the controller 406 controls the first switching unit 409 to use the external power source, and prevents the battery charging through the second switching unit 410 (S105).

If it is determined that the current time is the power saving time zone, the controller 406 confirms the remaining amount of the current battery 402 through the auxiliary power amount sensing unit 405 (S106). That is, if the controller 406 corresponds to the power save time period, but the battery remaining amount is insufficient, the first switching unit 409 is controlled to use the external power source, and the battery charging is prevented through the second switching unit 410 S105). On the other hand, if the controller 406 is in the power save time zone and the battery remaining amount is sufficient, the control unit 406 controls the battery to be used as a power source (S107).

For the step S107, the control unit 406 can prevent the battery from being charged by controlling the first switching unit 409 to shut off the external power supply. However, according to another embodiment, when the self-generated power is used as the external power source, the application of step 107 corresponds to the power saving period, and even if the remaining battery level is sufficient, Power can be designed to be used. Also, the auxiliary power storage unit 402 can be controlled not only by using a battery detached from the inside of the apparatus but also by using an external battery (e.g., a 'home battery', not shown) provided in the host. That is, for example, in the case where the home battery is used, in step 107, a control signal for using the home battery is generated if the power saving period corresponds to the power saving period and the remaining amount of the home battery is sufficient. The home battery use control signal may be generated directly from the electronic device 400 or through the smart server 201 in the customer.

According to step S107, the battery is used as a used power source through the discharging circuit unit 404, and the control unit 406 continuously checks whether the remaining battery power is insufficient as the used power source through the auxiliary power amount sensing unit 405 (S108 ).

If it is determined in step S108 that the battery remaining amount is insufficient as the used power source, it is determined whether the power saving time period has ended (S109). That is, the controller 406 controls the first switching unit 409 to use an external power source instead of the battery if the remaining battery power is insufficient and the power saving time period has not ended, (S105). The control unit 406 controls the first switching unit 409 to use an external power source instead of the battery if the remaining power of the battery is insufficient but the power saving time period has ended and allows the battery charging via the second switching unit 410 (S104).

During steps S104 and S105, it is possible to continuously check whether or not the power saving time zone is present (S102), and the control processor can be continuously executed without interruption (A). That is, for example, it is possible to check whether the conditions of S102 and S106 are satisfied even in an environment in which the external power source is being utilized as the used power source in step S104, thereby switching the battery power to the used power source instead of the external power source.

That is, according to an embodiment of the present invention, in a high-charge charging period or a power-requiring period determined as the power saving period, power is not charged from the external power supply, It is possible. It is also possible to selectively charge the battery depending on the remaining battery level. In addition, it is also possible to prepare for charging the battery at a later time by using external power while charging the battery at a time other than the power saving time.

5 is a flowchart showing another example of a power supply control method in an electronic device according to the first embodiment of the present invention. For example, the flowchart of FIG. 5 relates to an example in which the electronic device is operated by receiving a power save command from an external control device (for example, smart server 201) rather than determining the power saving time zone.

That is, the example of FIG. 5 does not directly determine the power save time zone by directly receiving the power information (for example, power charge information and / or power demand information) as described above in a general electronic device, Means a method of performing power supply selection control based on the power saving command received from an external control device such as the server 201.

4, the power information reception step S101 is replaced with the power control command reception step S201, and the power saving time period determination steps S102 and S109 are performed in the power saving command recognition step S202 and S209 Respectively. This will be described in detail as follows.

The power information receiving unit 407 receives the power control command through the smart grid power information network 100 or the internal control device 201 (S201). The control unit 406 confirms whether or not the received power control command includes a power save command (S202). As described above, the power saving command is an instruction to transmit to the electronic device after determining that the power saving time corresponds to the power saving time period in the external control device 201, and includes information on the power saving time period or a specific time period .

If it is determined by the control unit 406 that there is no power save command at the current time, the controller 406 checks the amount of charge of the current battery 402 through the auxiliary power amount sensing unit 405 (S203). That is, when there is no power save command and the battery remaining amount is insufficient, the control unit 406 controls the first switching unit 409 to use the external power source and allows the battery charging through the second switching unit 410 (S204). On the other hand, if there is no power save command but the battery remaining amount is sufficient, the controller 406 controls the first switching unit 409 to use the external power source, and prevents the battery charging through the second switching unit 410 (S205).

If it is determined at step S202 that there is a power save command at the current time, the controller 406 confirms the charge amount of the current battery 402 through the auxiliary power amount sensing unit 405 (S206). That is, when there is a power save command but the battery remaining amount is insufficient, the controller 406 controls the first switching unit 409 to use the external power source, and prevents the battery charging through the second switching unit 410 S205). On the other hand, if the power save command exists and the remaining battery power is sufficient, the controller 406 controls the battery to be used as a power source (S207). For the step S207, the control unit 406 can prevent the battery from being charged by controlling the first switching unit 409 to shut off the external power source.

In step S207, the battery is used as the in-use power source through the discharge circuit unit 404, and the control unit 406 continuously checks whether the remaining battery power is insufficient as the used power source through the auxiliary power amount sensing unit 405 (S208).

If it is determined in step S208 that the battery remaining amount is insufficient as the used power source, it is determined whether the power save command still exists (S209). However, if it is determined in step S202 that there is a predetermined end time value in a specific time zone or interval, the step S209 may be performed by determining whether the end time reference value is reached or not.

That is, if the remaining capacity of the battery is insufficient and the power save command is not terminated, the control unit 406 controls the first switching unit 409 to use an external power source instead of the battery, (S205). If the power save command is terminated, the controller 406 controls the first switching unit 409 to use an external power source instead of the battery, and allows the battery to be charged through the second switching unit 410 (S204).

Also, during the execution of steps S204 and S205, it is possible to continuously check whether or not the power save command is received (S202), so that the control processor can be continuously executed without interruption (B). That is, for example, in step S204, it is possible to check whether the external power source is being used as the used power source and satisfy the conditions of step S202 and step S206, thereby switching the battery power to the used power source instead of the external power source.

6A to 6D illustrate an example of a notification message screen provided to the user through the display unit 408 according to the first embodiment of the present invention. It is necessary to provide a notification message to the user through the display screen at the time of performing the control for each control step of FIGs. 4 and 5 described above.

For example, FIG. 6A shows an example of message notification in steps S107 and S207 of the control step. That is, since steps S107 and S207 correspond to the power saving time period and the battery power is used, for example, a message "Battery is used for the power saving time period, battery can not be charged for the power saving time" And displays it on the screen in the form of a screen 408a. The current power status currently being used can be provided in the form of graphic or text on one side of the display 408. For example, a power saving instruction graphic 424 indicating a current power saving time period and displaying a time (for example, two hours) during which the power saving time period is continued, a battery graphic 423 displaying a current battery charging status, (For example, 80%), a power available instruction text 422 for displaying the available time (e.g., one hour) of the battery currently used as the power source, and the like are displayed. In addition, although the battery is not charged because it is the current power saving time zone, the battery charging button 420 may be further provided so that the battery can be charged according to the user's selection. Accordingly, the user can charge the battery by selecting the corresponding battery charging button 420 when charging the battery by referring to the displayed graphic or text.

For example, FIG. 6B shows an example of message notification in steps S104 and S204 of the control step. That is, since steps S104 and S204 do not correspond to the power saving time period and the remaining battery capacity is not sufficient, the message "External power is being used and battery charging starts" is displayed in the form of a popup screen 408b On the screen. The current power status currently being used can be provided in the form of graphic or text on one side of the display 408. For example, an external power usage guide graphic 434 indicating that the external power source is currently in use, a battery graphic 433 displaying the current battery charge status, a battery (not shown) A charge amount guidance text 431, a guidance text 432 for displaying the time required for battery charging (for example, one hour), and the like are displayed. In addition, a battery charge cancellation button 430 may be further provided to enable the battery charge cancellation according to the user's choice while the battery is currently being charged. Accordingly, if the user desires to cancel the battery charging by referring to the displayed graphic or text, the user can select not to charge the battery by selecting the corresponding battery charge cancel button 430.

For example, FIG. 6C shows an example of message notification in steps S105 and S205 of the control step. That is, when the step S105 (or step S205) is the step proceeding through the step S106 (or step S206) or the step S109 (or step S209), it means that the battery is not charged because " A message is displayed on the screen in the form of a popup screen 408c. The current power status currently being used can be provided in the form of graphic or text on one side of the display 408. For example, an external power usage guide graphic 445 indicating that the external power is currently in use, a power saving guide graphic 444 indicating a current power saving time period and a time (for example, two hours) during which the power saving time period is continued, A battery graphic 443 for displaying the state of charge of the battery, a battery charge amount guidance text 441 for displaying the amount of charge (for example, 20%) in the battery, a guide for displaying the time required for charging the battery Text 442, and the like are displayed. Also, the battery charging button 440 may be further provided to charge the battery according to the user's selection although the battery charging is not performed because it is the current power saving time zone. Accordingly, the user can charge the battery by selecting the corresponding battery charging button 440 when charging the battery by referring to the displayed graphic or text.

In addition, for example, FIG. 6D shows another example of message notification in steps S105 and S205 of the control step. That is, if the step S105 (or step S205) is the step proceeding through step S103 (or step S203), a pop-up message saying "external power is in use, And displays it on the screen in the form of a screen 408d. The current power status currently in use can be provided to the other side of the display 408 in graphic or text form. For example, an external power usage instruction graphic 454 indicating that the external power source is currently in use, a battery graphic 453 indicating the current battery charging status, a battery (not shown) A charge amount guidance text 451, a guide text 452 for displaying the time required for battery charging (e.g., 10 minutes), and the like. In addition, the battery charging button 450 may be further provided to charge the battery according to the user's selection although the current battery amount (e.g., 80%) is sufficient to perform battery charging. Accordingly, the user can charge the battery by selecting the corresponding battery charging button 450 when charging the battery by referring to the displayed graphic or text.

6A to 6D, it is also possible that the user himself or herself can select the power source or charge the battery. In this case, the control unit 406 receives the user command and controls the first switching unit 409 and the second switching unit 409, And / or the switching operation of the second switching unit (410).

7A is a block diagram showing an electronic device according to a second embodiment of the present invention, and is a flowchart showing a power supply control method in an electronic device according to a second embodiment of the present invention. Hereinafter, a second embodiment of the present invention will be described in detail with reference to FIGS. 7A and 7B.

As shown in the figure, the electronic apparatus of FIG. 7A includes only the first switching unit 409 for selecting the power source, and there is no second switching unit 410 for selecting whether to charge the battery in FIG. Hereinafter, description will be made with reference to FIGS. 7A and 7B.

The control unit 501 determines whether or not the power saving time zone is determined from the received power information S301 (S302). The power saving time zone determination method is applicable in the same manner as described above with reference to FIG. 3 and FIG.

If it is determined that the current time is not the power saving time period, the first switching unit 409 is controlled to use the external power as the used power (S303). If it is determined that the power saving time is in the power saving period, the remaining battery power is checked through the auxiliary power detection unit 502 (S304).

Thereafter, when the power saving time falls but the battery remaining amount is insufficient, the first switching unit 409 is controlled to continuously use the external power as the used power (S303). On the other hand, if the battery is in the power save time zone but the battery remaining amount is sufficient, the external power is shut off by controlling the first switching unit 409 to utilize the battery power as the used power (S304).

Thereafter, it is determined whether the remaining amount of the battery is insufficient as the used power by the battery discharge (S306). If the remaining amount of the battery is insufficient as the used power, the first switching unit 409 is controlled again to utilize the external power as the used power (S303).

Accordingly, in the case of using the control processor, it is possible to selectively use the external power or the battery power as the used power depending on the power save time and the remaining battery power.

Although not shown in FIG. 7B, it should be apparent that the flowchart of FIG. 7B can be modified and utilized as a control method according to whether or not the power save command is received as in FIG.

FIG. 8A is a block diagram showing an electronic device according to a third embodiment of the present invention, and FIG. 8B is a flowchart showing a power supply control method in an electronic device according to a third embodiment of the present invention. Hereinafter, a third embodiment of the present invention will be described in detail with reference to FIGS. 8A and 8B.

As shown in FIG. 8A, the electronic apparatus of FIG. 8A includes only the second switching unit 410 for selecting whether to charge the battery, and the first switching unit 409 for selecting the power source is not present . The following description will be made with reference to FIGS. 8A and 8B. However, the embodiment of FIG. 8A relates to the case where only the external power source is utilized as the used power source in the state where the external power source is connected.

The control unit 601 determines whether or not the power saving time zone is determined from the received power information S401 (S402). The power saving time zone determination method is applicable in the same manner as described above with reference to FIG. 3 and FIG.

If it is determined that the battery is in the power save time zone, the second switching unit 410 is controlled to prevent the battery from being charged by the external power source (S403). If it is determined that the time is not the power save time period, the remaining battery power is confirmed through the auxiliary power amount sensing unit 602 (S404). Thereafter, if the remaining battery power is not the power saving time period, the second switching unit 410 is controlled to prevent the battery from being charged by the external power supply (S403).

If the battery remaining amount is insufficient, the second switching unit 410 is controlled to charge the battery using the external power source (S304).

Therefore, in the case of using the control processor, it is possible to selectively determine whether or not the battery is charged according to the power saving time zone and the remaining battery power. This makes it possible to prevent unnecessary and inefficient battery charging when the remaining battery power is sufficient or when the power saving time falls.

Although not shown in FIG. 8B, it should be apparent that the flowchart of FIG. 8B may be modified and utilized as a control method according to whether or not the power save command is received as in FIG.

Hereinafter, an electronic apparatus and a power supply control method thereof according to a fourth embodiment of the present invention will be described in detail.

9A is a block diagram showing an electronic apparatus according to a fourth embodiment of the present invention. 9A, an electronic device 500 according to the present embodiment includes a DC power input unit 502, an AC power input unit 502, an external power supply unit 506, an auxiliary power storage unit 508 (for example, The power supply unit 518, the display unit 520, the first switching unit 522, and the second switching unit 524, And a third switching unit 524.

However, the above-described configuration is shown as functional blocks for convenience of explanation. In actual implementation, the configuration may exist in a single configuration or may be implemented by a software program. Further, in a specific embodiment of the present invention, some of the above-described components may be additional components that are not necessarily required components.

The DC power input unit 502 receives the DC power supplied from the external DC power storage unit and supplies the DC power to the external power unit. At this time, the DC power storage device may be a variety of home power magnetic field devices.

The AC power input unit 504 receives the AC power supplied from the external AC power supply and supplies the AC power to the external power supply unit.

The third switching unit is connected to the AC power input unit 502 and the DC power input unit 502 to select either the AC power or the DC power as the used power.

The external power supply unit 506 receives power from the outside of the electronic equipment through the AC power input unit 502 or the DC power input unit 502 and supplies power within the equipment. The external power source may be the self-generated power generated by self-generated electricity (eg, solar energy, wind energy, etc.) in the consumer as well as the electricity provided by the electric utility with the electric fee.

The auxiliary power storage unit 508 charges and stores electric power through the charging circuit unit 510 and supplies power to the device through the discharging circuit unit 512. The auxiliary power detection unit 514 checks the amount of available power or the amount of power charged in the auxiliary power storage unit 508, and transmits the amount of power or the amount of power to the control unit 516.

The power information receiving unit 518 receives power information through the smart grid power information network 100 or the internal network 200. [ However, the power information may be a power control command received from an external control device (e.g., smart server 201). In addition, the power information may be provided in real time or periodically provided on a predetermined time unit basis. Also, the type of the power information may be at least either the electric power rate information or the electric power demand information. Depending on the design, it is possible to include both the electric power rate information and the electric power demand information.

Also, the power information receiving unit 518 can receive the self power generation information. The self-generated information may include information that indicates whether the self-generated amount information in the customer, available surplus self-generated power amount information, and the current power supplied to the external power source are self-generated power.

Specifically, for example, the electric power rate information refers to information on the electric power rate that can be changed in real time or periodically, and includes information on the electric power rate per use electric power in a certain time unit. Accordingly, when the electric power charge information is received, the electric power charge in the current time zone can be confirmed, and it is possible to classify the electric power charge according to the setting criteria into a high-cost charging section or a low-cost charging section. For example, a power-providing company directs electricity charges at a point in time when electricity demand is high (referred to as "peak time") to a high-rate charge, thereby reducing the user's electricity use. On the other hand, the electric power charge at the time of low electricity demand is set as a low cost charge, thereby inducing the user to use electricity in the low charge time zone to avoid the high cost charge period.

In addition, the power demand information refers to information on power demand varying in real time or periodically, and it is possible to analyze the previous power use sun of each customer through the smart grid power information network 100, And it is calculated based on the received power amount information. Accordingly, when the electric power demand information is received, the electric power demand in the current time zone can be confirmed, and it can be classified into an over demand period or a low demand period according to a setting standard. For example, in an electricity demanding high demand period, the user is guided to reduce electricity usage by setting a high electricity rate or by imposing a separate incentive or penalty regardless of the electricity rate.

Accordingly, the control unit 516 determines the power saving time zone from the power information received by the power information receiving unit 518 and determines the selection of the power source corresponding thereto. For example, the power saving time period can be determined as a high power billing interval or a power saving period as a power saving time zone, and it is possible to freely set whether a specific interval is a high billing interval or a demanding interval, by a user or a system.

The third switching unit 524 is connected to the first switching unit 522 and the third switching unit 524. The first switching unit 522 is configured such that it can select whether the external power source is to be utilized as the device using power under the control of the controller 516, When the external power source is used as the power source for the apparatus, it is designed to be capable of selecting whether to use the AC power or the DC power.

In addition to the display function inherent to the device itself, the display unit 520 performs a function of providing a message to the user whether to select a power source according to the operation of the control unit 516 and to charge the battery.

9B is a flowchart showing a power supply control method in an electronic apparatus according to a fourth embodiment of the present invention. Hereinafter, a fourth embodiment of the present invention will be described in detail with reference to FIG. 9B.

First, the power information receiving unit 518 receives power information through the smart grid power information network 100 or the internal network 200 (S502). The control unit 516 determines whether the current time is the power saving time zone from the received power information (S504). As described above, the power saving time period may correspond to, for example, a case where it is judged from the electric power charge information to be a high-cost charging interval or from the power demand information to the excessive demand period.

If it is determined by the control unit 516 that the current time is not the power saving time period, the controller 516 controls the first switching unit 522 and the third switching unit to use the external AC power (S506).

At this time, as shown in FIG. 10A, for example, a message "External AC power is being used and battery charging is started" is displayed on the display in the form of a popup screen 408b. And may provide the power status currently in use through the display unit 520 in the form of graphic or text. For example, an external power usage guide graphic 434 indicating that the external power source is currently in use, a battery graphic 433 displaying the current battery charge status, a battery (not shown) A charge amount guidance text 431, a guidance text 432 for displaying the time required for battery charging (for example, one hour), and the like are displayed. In addition, a battery charge cancellation button 430 may be further provided to enable the battery charge cancellation according to the user's choice while the battery is currently being charged. Accordingly, if the user desires to cancel the battery charging by referring to the displayed graphic or text, the user can select not to charge the battery by selecting the corresponding battery charge cancel button 430.

If the current time corresponds to the power saving time period, the controller 516 checks the remaining amount of the battery 508 through the auxiliary power detecting unit 514 (S508).

At this time, if the remaining capacity of the battery is insufficient, the control unit 516 determines whether the external DC power, that is, the amount of electric power charged in the DC power storage unit, is sufficient (S512) The first switching unit 522 and the third switching unit are controlled to be used (S514).

At this time, as shown in Fig. 10B, for example, a message "Battery is not charged because the external DC power source is in use or the power save time period" may be displayed on the screen in the form of a popup screen 520c. It is possible to provide the power status currently in use to one side of the display unit 520 in the form of graphic or text. For example, a power usage guide graphic 545 indicating that the external DC power is currently in use, a power saving guide graphic 544 indicating a current power saving time period and a time (e.g., two hours) during which the power saving time period is continued, A battery graphic 543 for displaying the state of charge of the battery, a battery charge amount guidance text 541 for displaying the amount of charge (for example, 20%) in the battery, a guide for displaying the time required for charging the battery Text 542, and the like are displayed. Also, the battery charging button 540 may be further provided to charge the battery according to the user's selection although the battery charging is not performed since the current power saving time period. Accordingly, the user can charge the battery by selecting the corresponding battery charging button 540 if the user wishes to charge the battery by referring to the displayed graphic or text.

On the other hand, when the battery remaining amount and the charged power amount of the DC power storage unit are insufficient, the controller 516 controls the first switching unit 522 and the third switching unit to use the external AC power (S506 ).

On the other hand, if the controller 516 is in the power save time zone and the battery remaining amount is sufficient, the control unit 516 controls the battery to be used as a power source (S510).

6A, a message "Battery is not used during the power saving period" is displayed on the popup screen (for example, " 408a. ≪ / RTI > For example, a power saving instruction graphic 424 indicating a current power saving time period and displaying a time (for example, two hours) during which the power saving time period is continued, a battery graphic 423 displaying a current battery charging status, (For example, 80%), a power availability guide text 422 for indicating the available time (for example, 1 hour) of the battery currently used as the power source, and the like are displayed. In addition, although the battery is not charged because it is the current power saving time zone, the battery charging button 420 may be further provided so that the battery can be charged according to the user's selection. Accordingly, the user can charge the battery by selecting the corresponding battery charging button 420 when charging the battery by referring to the displayed graphic or text.

In addition, the control unit 516 may continuously check whether or not the power saving time zone is present so that the control processor is continuously executed without interruption. In other words, for example, it is possible to continuously receive power information even in an environment where external DC power or AC power is being used, and switch the battery power to the used power instead of the external power Do.

That is, in the present embodiment, it is possible to use the electric power already charged in the battery instead of using the high-cost electric power supplied from the outside in the high-charge charging period or the power charge period determined as the power saving period. In addition, it is possible to selectively use external DC power that is pre-charged depending on the power save time period or the remaining battery level.

401: external power supply unit 401: auxiliary power storage unit
405: auxiliary power amount sensing unit 406:
407: Power information receiving unit 408:
409: first switching unit 410: second switching unit

Claims (17)

An external power supply unit supplied with external power,
An auxiliary power storage unit for receiving electric power from the external power supply unit and charging and storing the electric power,
A first switching unit connected to the external power supply unit and the auxiliary power storage unit to select one of the external power supply unit and the auxiliary power storage unit as a power source,
A second switching unit for selecting whether to charge the auxiliary power storage unit using the external power supply,
An auxiliary power amount sensing unit for sensing an auxiliary power amount charged in the auxiliary power storage unit,
A power information receiver for receiving power information including at least one of power charge information or power demand information,
A controller for controlling the first switching unit and the second switching unit based on the power information received from the power information receiver and the auxiliary power detected by the auxiliary power detector,
And a display unit for providing a message indicating whether the selected power source type and the auxiliary power storage unit are charged according to the operation of the control unit,
Wherein the control unit determines the overcharge period of the high-rate charging period or the power demand information of the power charge information as the power saving period and controls the first switching unit to select the auxiliary power storage unit as the power source of the power saving period, And controls the second switching unit to shut off charging of the auxiliary power storage unit in the power saving period. delete delete delete The method according to claim 1,
Wherein the controller controls the second switching unit to charge the auxiliary power storage unit with the external power when the auxiliary power detected by the auxiliary power detection unit is less than or equal to a reference value and is not the power saving period. The method according to claim 1,
Wherein the control unit controls the first switching unit to select the external power source as a power source when the auxiliary power detected by the auxiliary power detection unit is less than a reference value. The method according to claim 1,
An AC power input unit for receiving an AC power supplied from an external AC power supply and supplying the AC power to the external power supply unit,
A DC power input unit for receiving a DC power supplied from an external DC power storage device and supplying the DC power to the external power supply unit,
A third switching unit connected to the AC power input unit and the DC power input unit to select one of the AC power and the DC power as the used power,
Lt; / RTI >
And the control unit controls the third switching unit to select either the AC power or the DC power as the power source based on the power information. 8. The method of claim 7,
Wherein the controller determines the overcharge period of the high-rate charging period or the power demand information of the power charge information as the power saving period and controls the third switching unit to select the DC power source as the power source during the power saving period. 8. The method of claim 7,
Wherein the control unit controls the third switching unit to select the AC power source as the power source when the amount of DC power stored in the external DC power storage device is lower than a reference value. delete delete delete delete delete delete delete delete

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