KR20100060178A - Non-contact charge remote controller and charge control method thereof - Google Patents

Abstract

PURPOSE: A non-contact charge remote controller and a charge controlling method thereof are provided to prevent unnecessary power waste by activating a power transmission system of the main device in a power transmission mode for charging a battery. CONSTITUTION: A control block(1102) and an infrared ray transmission block(1103) monitors the amount of charge of the battery and transmits a charge request signal or charge completion signal to the main device. A power receiving block(1106) wirelessly receives the charge power from the main device in response to a charge request signal. A charge control block(1105) notifies the charge completion time of the chargeable battery to the control block and the infrared ray receiving block. The charge power is received as an ultrasonic wave or micro wave signal.

Description

Non-contact charging remote control and charging control method {NON-CONTACT CHARGE REMOTE CONTROLLER AND CHARGE CONTROL METHOD THEREOF}

The present invention relates to a remote control used for remote control of various electronic devices, and more particularly, a non-contact suitable for wirelessly charging a battery of a remote control used for controlling various electronic devices (eg, home appliances, office equipment, etc.). A charging remote controller and a charging control method thereof.

As is well known, various electronic devices, such as televisions, receivers, DVD players, PVRs, fans, air conditioners, and the like, employ a function of remotely controlling various operations to increase convenience in use. The remote control function is performed through a remote controller (remote controller) provided separately.

That is, the user controls the operation of the electronic device from a remote location through a simple remote operation of the remote controller corresponding to the electronic device to be controlled by the user. The remote controller is provided with its own power source such as a battery or a rechargeable battery. Here, the present invention relates to an improvement of a charging remote controller having a rechargeable battery.

As such, a conventional remote control having a charging function is disclosed in Korean Laid-Open Patent Publication No. 2008-64668 published on July 9, 2008 (name: a chargeable remote control having a USB terminal, hereinafter abbreviated as "prior patent"). There is.

That is, the prior patent has a USB terminal on the remote control side, a USB port on the peripheral device side, the USB terminal on the remote control side draws out the battery provided in the remote control by inserting the USB port provided on the peripheral device side Will charge.

Therefore, when the battery of the remote controller is exhausted, the user can charge the battery of the remote controller by inserting the USB terminal of the remote controller into the USB port of the peripheral device.

However, the above-described conventional method of charging the battery of the remote controller using the USB terminal and the USB port is still inconvenient to use because the user must directly connect the USB port of the remote controller and the USB port of the peripheral device directly. There is a problem that results.

Therefore, if the battery of the remote controller is charged without a physical connection operation by the user, the user's convenience will be further enhanced, but at present, there is no suggestion for such a technique.

According to one aspect of the present invention, there is provided a remote controller having a function of charging a built-in rechargeable battery. Control / sending means for generating a charging completion signal and wirelessly transmitting the charging completion signal to the main body device according to the notification of the completion time of charging, and means for wirelessly receiving the charging power wirelessly transmitted from the main body device in response to the charging request signal; And a means for charging the rechargeable battery by using the received charging power, and monitoring the charging state to notify the control / distributing means of the detection result when the charging completion time is detected. To provide.

According to another aspect of the present invention, there is provided a method of controlling charging of a rechargeable battery built in a remote controller, the method comprising: generating a charging request signal for charging the rechargeable battery and wirelessly transmitting the charging request signal to a main body device; In response to a signal, wirelessly transmitting charging power to the remote controller through a power transmission system of the main body device, executing a charging mode of charging the rechargeable battery using the received charging power; Monitoring the charging state of the rechargeable battery and ending the charging mode when the completion time of charging is detected, generating a charging completion signal and wirelessly transmitting the charging completion signal to the main body device; and in response to the received charging completion signal, Charging control method of the non-contact charging remote control including the step of blocking the wireless transmission of the charging power Provided.

According to another aspect of the present invention, there is provided a remote controller having a function of charging a built-in rechargeable battery, comprising: means for generating an operation signal for starting charging of the rechargeable battery in response to a user operation; A control / transmission means for generating a charge request signal according to the signal and transmitting it wirelessly to the main body device, and generating a charge completion signal and transmitting the signal to the main body device according to a notification at the time of completion of charging, and in response to the charge request signal; Means for wirelessly receiving the charging power wirelessly transmitted from the main body device and charging the rechargeable battery using the received charging power, and monitoring the charging state to detect the detection result when the charging completion time is detected. Provided is a non-contact charging remote control including means for informing the control / distributing means.

The present invention provides a remote control battery by charging a built-in rechargeable battery by receiving the charging power wirelessly transmitted in the form of an ultrasonic wave or a microwave signal from a main body device in the form of a remote controller without physically connecting the remote controller to a peripheral device for charging the battery. The user's ease of use for the charging of can be further enhanced.

According to the technical aspect of the present invention, unlike the aforementioned conventional method of charging the battery of the remote controller by physically connecting the USB terminal and the USB port, the main body apparatus wirelessly transmits the charging power in response to a charge request from the remote controller side, By receiving this from the remote controller side to charge the built-in rechargeable battery (non-contact charging), the present invention can effectively solve the problem in the conventional manner through such technical means.

Here, the main body device means, for example, an electronic device for home or office use, and the charging power can be transmitted as a signal such as an ultrasonic wave or a microwave.

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

FIG. 1 is a block diagram of a non-contact charging system including a non-contact charging remote controller according to an exemplary embodiment of the present invention, and includes a remote controller side 110 and a main body device side 120.

Referring to FIG. 1, the remote controller 110 refers to a non-contact charging remote controller of the present invention, and includes an operation signal generation block 1101, a control block 1102, an infrared ray transmission block 1103, and a rechargeable battery 1104. , A charge control block 1105, a power receiving block 1106, a direct current conversion block 1107, and the like. The main unit side 120 refers to an electronic device such as a television, a homenet, or the like, and includes an infrared reception block 1201, a control block 1202, a power generation block 1203, a power transmission block 1204, and the like. It includes.

First, the operation signal generation block 1101 generates various operation signals corresponding to a user operation through a keypad, a touch pad or a touch screen of a remote controller, and the operation signals generated here are transmitted to the control block 1102. do. Here, various operation signals may include an operation signal for starting charging.

Next, the control block 1102 includes, for example, a microprocessor for performing overall operation control performed on the remote controller, and when the operation signal according to the user's operation is input from the operation signal generation block 1101, infrared transmission is performed. In block 1103, an infrared signal corresponding to a user's operation is controlled to be transmitted.

In addition, the control block 1102 generates a charge request signal and transmits the charge request signal to the infrared transmitting block 1103 when a detection command for the charge start time is received from the charge control block 1105, and charges from the charge control block 1105. When the detection command for the completion time is received, the charging completion signal is generated and transmitted to the infrared ray transmitting block 1103.

In addition, the infrared ray transmitting block 1103 includes, for example, a diode for generating infrared rays, and in response to a control signal provided from the control block 1102, a remote control signal (infrared signal) of the main body device in response to a user operation. It provides a function such as to generate a wireless transmission and the like, for example, the charging request signal, the charging completion signal, and the like as the infrared signal wireless transmission.

Next, the charging control block 1105 monitors (periodically monitors) the amount of charge of the rechargeable battery 1104 when the remote controller is executing the standby mode, and checks (detects) whether or not the charging start time is reached, and charges. In the mode, the battery is charged by using the charging power (direct current) provided from the DC conversion block 1107, and when the charging mode is executed, the charging state of the charging battery 1104 is monitored to reach the completion point of charge. It provides a function such as checking (detecting) whether or not it is present, and also providing a function of notifying the detection result to the control block 1102 when the charging start time or the charging completion time is detected, respectively.

Here, the start point of charging refers to a point in time at which charging power of the rechargeable battery 1104 is consumed by a predetermined level to start charging, and the point of completion of charging refers to the point of charging battery 1104 through execution of the charging mode. ) May mean the point of time when the full state is reached.

In addition, the power reception block 1106 includes an antenna for receiving a radio signal, for example, and receives the charging power wirelessly transmitted from the power transmission block 1204 on the main body side 120 to receive the original signal before modulation. And demodulate the signal to the DC conversion block 1107. Here, the charging power may be received in the form of signals such as ultrasonic waves (RF, etc.), microwaves, and the like.

The DC conversion block 1107 includes, for example, a rectifier circuit and the like, and converts the AC power for charging transmitted from the power reception block 1106 into DC power to transfer the DC power to the charge control block 1105. To provide.

On the other hand, the infrared receiving block 1201 of the main body device side 120 receives the infrared signal (remote control signal of the main body device) transmitted from the infrared transmitting block 1103 of the remote control side 110 and converts it into an electrical signal. And demodulate the converted electrical signal to generate infrared code data (actual remote control signal), and deliver the generated remote control signal (infrared code data) to the control block 1202. . Here, the remote control signal may be, for example, a charge request signal, a charge complete signal, or the like.

Next, the control block 1202 includes, for example, a microprocessor for performing overall operation control performed in the main body apparatus, etc., and generates a control command corresponding to the remote control signal transmitted through the infrared reception block 1201. To deliver to the corresponding control target blocks (not shown) built in the main body device.

In addition, the control block 1202 activates the power transmission system when the charge request signal is transmitted from the infrared reception block 1201, that is, an external power source (ie, a main body) to the power generation block 1203 and the power transmission block 1204. External power input to the device). Herein, the power transmission system refers to a power generation block 1203 and a power transmission block 1204, and activation means power is applied to two blocks to perform an operation required for charging power transmission. .

Moreover, the control block 1202 deactivates the power supply system when the charge completion signal is transmitted from the infrared reception block 1201, that is, the external power supply to the power generation block 1203 and the power supply block 1204 is blocked. Control as possible.

Subsequently, the power generation block 1203 includes, for example, a power input terminal, a rectifying circuit, a switching circuit, a resonance circuit, and the like, when an activation control command (power supply command) is provided from the control block 1202. Executes the power discharging mode which is converted to the charging power and delivered to the electric power discharging block 1204, terminating the electric power discharging mode when the deactivation control command (power supply interrupting instruction) is provided from the control block 1202, and the like. Provides the functionality of

The power transmission block 1204 includes, for example, an antenna for receiving a wireless signal, and modulates the charging power provided from the power generation block 1203 into a signal such as an ultrasonic wave or a microwave to wirelessly transmit (that is, Wireless transmission to the power reception block 1106 of the remote control unit 110).

Next, a series of processes for charging the rechargeable battery provided in the non-contact charging remote controller of the present invention having the above-described configuration will be described.

2 is a flowchart illustrating a process of charging a rechargeable battery built in a charging remote controller in a non-contact manner according to an exemplary embodiment of the present invention.

Referring to FIG. 2, while the remote controller executes a standby mode (or an operation mode) (step 202), the charging control block 1105 monitors the charging amount (remaining current amount) of the rechargeable battery 1104 at a predetermined period ( Step 204).

As a result of the monitoring in step 204, when it is determined that the current charge level reaches the start of charging (step 206), the charging control block 1105 notifies the control block 1102, and in response to the control The block 1102 generates a charge request signal and transmits it to the infrared transmission block 1103, whereby the infrared charge request signal is wirelessly transmitted and transmitted to the infrared reception block 1201 on the main unit side 120 (step 208). .

Next, the infrared reception block 1201 demodulates the received charge request signal into an original signal and then transfers it to the control block 1202. In response, the control block 1202 activates the power transmission system, that is, a power generation block. In step 210, external power is applied to the power transmission block 1204 and the power transmission block 1204.

Accordingly, the power generation block 1203 executes the power delivery mode of converting external power into charging power and delivering the power to the power delivery block 1204 (step 212). As a result, the power generation block 1204 generates the power generation block. The charging power transmitted from 1203 is modulated into a signal such as an ultrasonic wave or a microwave to wirelessly transmit, that is, wirelessly transmit to the power receiving block 1106 of the remote controller side 110. That is, the power transmission mode in which the main body device side 120 wirelessly transmits the charging power to the remote controller side 110 through the power transmission system is executed.

Next, the power receiving block 1106 receives the charging power wirelessly transmitted from the power transmitting block 1204, demodulates the original signal before modulation, and transmits the demodulated signal to the DC conversion block 1107, and then the DC conversion block 1107. This charging AC power is converted into DC power and transferred to the charging control block 1105, whereby the charging mode in which the charging control block 1105 charges the charging battery 1104 using the converted DC power is executed. (Step 214).

The charging control block 1105 then monitors the charging state of the charging battery 1104 while executing the charging mode to detect whether the charging completion time is reached (steps 216 and 218).

If it is determined that the charging completion point has been reached as a result of the detection in step 218, the charging control block 1105 terminates the charging mode and then notifies the control block 1102 of the detection of the charging completion point (step 220). In response thereto, the control block 1102 generates a charging completion signal and transmits the charging completion signal to the infrared transmission block 1103, whereby the infrared charging completion signal is transmitted wirelessly and the infrared reception block 1201 of the main unit side 120 is transmitted. Is passed (step 222).

Next, the infrared reception block 1201 demodulates the received charge completion signal into an original signal and then transmits the demodulated signal to the control block 1202. In response, the control block 1202 deactivates the power transmission system, that is, a power generation block. Control to block the external power supply to the 1203 and the power transmission system 1204 (step 224).

As a result, the power generation block 1203 terminates the power delivery mode, whereby wireless transmission of charging power is interrupted.

That is, in the present invention, the power supply system of the main body device is activated (powered) only when the power supply mode for charging the rechargeable battery included in the remote controller is executed (otherwise, the power supply system is deactivated). This can prevent unnecessary waste of power in the device.

Meanwhile, in the embodiment of the present invention, the charging mode (power delivery mode on the main unit side) is executed based on the result of checking the charge amount of the rechargeable battery provided on the remote controller. The present invention is not limited thereto, and the charging mode may be manually set according to a user's operation.

That is, when the charging status of the rechargeable battery is displayed on the operation panel of the remote controller and the user views the charging status and manipulates the charging start (when an investigation user signal for starting charging is generated), the remote controller charge request signal is displayed. Generate and wirelessly transmit to the main body device side, and in response to the main body device generates a charging power to perform a wireless transmission to the remote control side to execute the charging mode. In this case, the method of ending the charging mode may be applied in the same manner (detection of the completion point of charging).

In this case, unlike the method of periodically monitoring the charge amount of the rechargeable battery, since the algorithm for monitoring the charge amount of the rechargeable battery included in the remote controller does not need to be separately installed, it is possible to simplify and reduce the cost of the remote control control algorithm. You will get a different effect.

In the above description has been described by presenting a preferred embodiment of the present invention, but the present invention is not necessarily limited to this, and those skilled in the art to which the present invention pertains within a range without departing from the technical spirit of the present invention It will be readily appreciated that branch substitutions, modifications and variations are possible.

1 is a block diagram of a non-contact charging system including a non-contact charging remote control according to an embodiment of the present invention;

2 is a flowchart illustrating a process of charging a rechargeable battery built in a charging remote controller in a non-contact manner according to an exemplary embodiment of the present invention.

Description of the Related Art

110: remote control side 120: main unit side

1101: operation signal generation block 1102, 1202: control block

1103: infrared transmission block 1104: rechargeable battery

1105: charge control block 1106: power receiving block

1107: DC conversion block 1201: infrared receiving block

1203: power generation block 1204: power transmission block

Claims (9)

A remote control having a function to charge the built-in rechargeable battery, Control / sending means for monitoring the charge amount of the rechargeable battery to generate a charge request signal and wirelessly transmit it to the main body device at the charging start time, and generate a charge completion signal and wirelessly transmit the charge completion signal to the main body device according to the notification of the completion of charge. and, Means for wirelessly receiving charging power wirelessly transmitted from the main body device in response to the charging request signal; Means for charging the rechargeable battery using the received charging power, monitoring the charging state, and notifying the control / distributing means of the detection result when the charge completion time is detected. Non-contact charging remote control comprising a. The method of claim 1, The charging power is a non-contact charging remote control, characterized in that received as an ultrasonic or microwave signal. As a method of controlling the charge of the rechargeable battery built into the remote control, Generating a charge request signal for charging the rechargeable battery and wirelessly transmitting the charge request signal to the main body device; In response to the received charge request signal, wirelessly transmitting charging power to the remote controller through a power transmission system of the main body device; Executing a charging mode of charging the rechargeable battery using the received charging power; Monitoring the state of charge of the rechargeable battery to terminate the charging mode when a charging completion time is detected, and generating a charging completion signal to wirelessly transmit the signal to the main body device; In response to the received charging completion signal, blocking wireless transmission of the charging power; Charge control method of the non-contact charging remote control comprising a. The method of claim 3, wherein The charging request signal is generated when the charging start time by monitoring the charging amount of the rechargeable battery, the charge control method of the non-contact charging remote control. The method of claim 3, wherein The charging request signal is generated when a user manipulation signal for starting to charge the rechargeable battery is input. The method according to any one of claims 3 to 5, The charging electric power is a charging control method of a non-contact charging remote control, characterized in that transmitted as an ultrasonic or microwave signal. The method according to any one of claims 3 to 5, The power transmission system, the charging control method of the non-contact charging remote control, characterized in that activated only when the wireless transmission of the charging power. A remote control having a function to charge the built-in rechargeable battery, Means for generating an operation signal for starting charging of the rechargeable battery in response to a user operation; Control / sending means for generating a charge request signal according to the generated operation signal and wirelessly transmitting the charge request signal to the main body device, and generating a charge completion signal and wirelessly transmitting the charge completion signal to the main body device according to a notification of a completion point of charge; Means for wirelessly receiving charging power wirelessly transmitted from the main body device in response to the charging request signal; Means for charging the rechargeable battery using the received charging power, monitoring the charging state, and notifying the control / distributing means of the detection result when the charge completion time is detected. Non-contact charging remote control comprising a. The method of claim 8, The charging power is a non-contact charging remote control, characterized in that received as an ultrasonic or microwave signal.

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