KR101486714B1 - The IR receiver module with blocking the standby power function - Google Patents

Abstract

The present invention relates to an infrared ray reception module configured to cut off a standby power of an electrical or an electronic product. According to an embodiment of the present invention, the infrared ray reception module includes: a diode outputting a detection signal; an infrared ray switching unit which includes a signal input unit, a first semiconductor switch, and a main switch; an infrared ray control unit which generates and outputs an infrared ray signal; and a CPU which receives and determines the infrared ray signal.

Description

[0001] The present invention relates to an infrared receiver module having a standby power interruption function,

The present invention relates to an infrared ray receiving module configured to receive infrared signals of a remote controller for electrical and electronic appliances and to interrupt standby power consumed by an infrared ray controller which is on / off driven. More specifically, the infrared power of the infrared receiving module and the switching power supply (SMPS) of the infrared receiving module, which were required to wait for the infrared signal of the remote controller, are cut off even when the electrical and electronic products are turned off, And more particularly, to an infrared ray receiving module having a minimized standby power interruption function.

2. Description of the Related Art Generally, a remote controller for electric and electronic products is used for controlling electrical and electronic equipments and devices located within a certain distance range, and is used for a video cassette recorder, an audio system, an air conditioner, And is widely used in such electric and electronic products.

Such a remote controller is provided with a plurality of buttons, and the user can conveniently set or change the functions of the electric / electronic product by operating buttons of the remote controller remotely. Because of the convenience of use of these remote controllers, they are widely used in most electric and electronic products on the market.

The remote controller for electric and electronic products is equipped with a built-in battery and is operated by the current of the battery. That is, when the user selects a desired button among the various buttons of the remote controller in which current flows, the function corresponding to the button is converted into an optical signal from the electric signal and transmitted to the built-in infrared receiving module of the electric / Off / Function).

For this purpose, only the infrared receiving module built in the electric / electronic product must keep the power on in order to recognize the on signal of the next remote controller even when the power of the electric / electronic product is turned off by the remote controller.

At this time, since the power of the infrared receiving module is supplied from the SMPS (switching mode power supply), standby power is continuously consumed in the SMPS and the infrared receiving module.

The stand-by power refers to the power consumed when the power plug of the electric / electronic product is plugged in and the power is turned off by the remote controller or the like, and the electric power consumed by the electric / , And each country is regulated by law.

More specifically, the International Energy Agency recommends countries to reduce the standby power of all electrical appliances to less than 1 watt (W). In Korea, as of 2010, domestic appliances and industrial products And less than 1W in 2015 and less than 0.5W in 2015 to reduce unnecessary power consumption.

FIG. 1 is a perspective view showing a configuration and a product of an infrared ray receiving module incorporated in a conventional electric / electronic product. Referring to FIG. 1, in the case of a conventional infrared ray receiving module, The power is continuously consumed to recognize the remote control on signal.

In general, the power consumed by the infrared receiving module is 0.1 ~ 0.2W, and the standby power consumed by the SMPS consumes 0.3 ~ 0.5W, satisfying the legal regulation less than 0.5W.

However, even if the standby power required for driving the infrared receiving module satisfies the legal regulations, the power consumption due to the standby power is separately required for each of the electric and electronic products. Therefore, the unnecessary power consumption is reduced There is no choice but to grow.

Accordingly, there has been a need for a means for effectively reducing energy consumption by minimizing standby power in the infrared receiving module incorporated in the electrical and electronic products by minimizing standby power.

In order to solve the above problems, Korean Patent Laid-Open Publication No. 10-2007-0097917 proposes a remote control signal power saving module.

As shown in FIG. 2, in the above-described publication, power generated by the remote control power supply unit 300 is directly supplied to the remote control receiving unit 100 and the control unit 200 to prevent consumption of main power to save energy .

In other words, power is independently produced using the solar light collecting plate film 320 and supplied to the remote control receiving unit 100 and the control unit 200. When the remote control receiving signal is received, the control unit 200 controls the electronic switch 400 are opened and closed to configure the module to operate.

However, in the case of the construction of such an open document, since independent power such as a separate solar photovoltaic film 320 is required to be constructed, the manufacturing cost is high, and the solar photovoltaic film 320 itself requires solar light There is a problem in that, in the case of electrical and electronic products installed in a basement or in a dark place inside the house, such a saving module can not actually operate.

In order to solve the above problems, the present invention is configured to block the power supply of the SMPS and all the standby power of the infrared control unit of the infrared receiving module upon receiving the off signal of the remote controller, The present invention aims to provide an infrared receiving module configured to be driven by an infrared control unit of an infrared receiving module and an SMPS through a separate infrared ray switching unit of power.

In order to achieve the above object, the present invention provides a remote control receiving module for an electric / electronic product, which receives an infrared signal of a remote control and receives power supplied from a power supply through a SMPS, A diode for outputting a detection signal; An infrared switching unit configured to receive power from the power supply unit through a high resistance and to receive a sensing signal from the diode at a signal input unit and to supply power from the power supply unit to the SMPS; An infrared control unit driven by receiving power from the energized SMPS to receive a sensing signal from the diode at the signal input unit and generating and outputting a signal processed infrared signal; And a CPU driven by receiving power from the SMPS and receiving a signal-processed infrared signal output from the infrared control unit to determine an infrared signal,

When the infrared signal signal processed by the CPU is determined as an on signal, a control signal is output to the infrared switching unit to drive the main switch of the infrared switching unit to continuously supply power from the power supply unit to the SMPS. An infrared receiver module with standby power interruption function is presented.

Wherein the infrared switching unit is provided with a high resistance for reducing power consumption of a power source input from the power source unit; A signal input unit connected to the diode to output a signal when a detection signal is input from the diode while the power source having the high resistance is inputted and remains active; A buffer for amplifying a signal output from the signal input unit; A first semiconductor switch triggered by a signal output through the buffer; And a coil connected between the power supply unit and the first semiconductor switch and supplied with a voltage from the power supply unit while the first semiconductor switch is driven and a contact operated by the coil to energize power from the power supply unit to the SMPS And a main switch.

The infrared switching unit may further include a second semiconductor switch connected to the coil and being triggered by a control signal output from the CPU while determining that the infrared signal is an on signal, The voltage of the power supply unit is continuously applied to the coil of the main switch so that the contact of the main switch is kept on.

Further, in the present invention, each of the signal input units of the infrared switching unit and the infrared control unit receiving the sensing signal from the diode is configured in a parallel structure.

The following effects can be achieved through the infrared ray receiving module having the standby power interruption function of the present invention.

First, an infrared switching unit driven by a low power consumption of 0.01 W to 0.04 W is separately provided in the infrared receiving module of the present invention. In the off state of an electrical and electronic product, an infrared control unit and an SMPS (Infrared) control module of an infrared receiving module and a switching mode power supply (SMPS), which are necessary for waiting for an infrared signal of a remote controller even when the power supply of a conventional electric / electronic product is off, , And standby power of about 0.5 W required for a CPU and the like is cut off, thereby minimizing power consumption.

Secondly, the infrared switching unit of the present invention drives the SMPS while receiving the sensing signal from the diode, and again drives the infrared control unit to receive the sensing signal from the infrared control unit and turn the power supply of the electric / The time required for the user to press the remote controller is changed from 0.3 second to 1 second, which is the time required for the user to press the remote controller. Thus, a time delay due to the addition of a separate infrared ray switching unit Standby power can be minimized without any problem.

1 is a circuit diagram and a product perspective view showing a remote control receiver module built in a conventional electric / electronic product.
2 is a block diagram of a conventional remote controller signal power saving module.
3 is a circuit configuration and a product perspective view of an infrared ray receiving module according to an embodiment of the present invention.
4 and 5 are views illustrating the operation principle of the infrared ray switching unit of the infrared ray receiving module according to the embodiment of the present invention.
6 is a conceptual diagram of a time required for converting the power supply of the electric / electronic product into the on state through the infrared ray receiving module of the present invention.

Hereinafter, an infrared ray receiving module having a standby power interruption function according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram and a perspective view of an infrared ray receiving module according to an embodiment of the present invention. The present invention relates to a remote control receiver module for an electric / electronic product, which receives an infrared signal of a remote controller and receives power supplied from a power supply unit through an SMPS.

When the power plug of the electric / electronic product is plugged in and the infrared signal is generated by pressing the remote controller, the infrared receiving module built in the electric / electronic product receives the infrared signal.

When the power of the electric / electronic product is turned off and the remote controller is turned on to generate an infrared signal, the diode 100 of the infrared receiver module receives the electric signal and outputs a detection signal.

In the present invention, the infrared switching unit 200 is configured such that the infrared switching unit 200 receives power from the power supply unit 300 through the high resistance 210 and maintains the standby state. The power source of the power source unit 300 is generally called B plus power source.

The high resistance 210 of the infrared switching unit 200 may have a size ranging from 1 MΩ to 4 MΩ and may be consumed in the high resistance 210 when a voltage of 170 V to 270 V, The power consumed by the infrared switching unit 200 can not be reduced to a very low power consumption of about 0.01 W to 0.04 W and the standby power of the infrared switching unit 200 can be neglected.

In other words, there is no standby power consumed in the infrared control unit 600, the SMPS 400, the CPU 500, and the like of the present invention while the power supply of the electrical and electronic products is off. In the infrared switching unit 200, Only a very small power consumption of about 0.04 W is used, so that the power consumed by the infrared receiving module of the present invention practically consumed by the standby power can be almost shut off.

More specifically, an infrared ray switching unit 200 driven by a low power consumption of 0.01 W to 0.04 W is separately provided in the infrared ray receiving module of the present invention. In the off state of the electric and electronic products, the infrared ray control unit 600 ), The SMPS 400, the CPU 500, and the like, so that the infrared control unit (not shown) of the infrared receiving module, which was necessary for waiting the on infrared signal of the remote controller even when the power supply of the conventional electric / 600, the SMPS 400, and the CPU 500, the power consumption is minimized.

Upon receiving the detection signal output from the diode 100 in the signal input unit 220 of the infrared switching unit 200, the main switch 230 is driven and power is supplied from the power supply unit 300 to the SMPS 400 .

Each of the signal input units of the infrared switching unit 200 and the infrared control unit 600 is configured to receive a sensing signal transmitted directly from the diode 100 in a parallel structure.

The detailed operation principle of the main switch 230 configured in the infrared switching unit 200 will be described later.

In addition, the infrared control unit 600 of the present invention is activated while the power is being input from the powered SMPS 400, receives a sensing signal from the diode 100 at the signal input unit, generates a signal-processed infrared signal, 500).

The CPU 500 is activated and powered by the power from the SMPS 400. The CPU 500 receives a signal processed infrared signal output from the infrared control unit 600 and determines whether the infrared signal is an on signal or an off signal .

That is, according to the present invention, when an infrared signal is generated from the remote controller, only the infrared switching unit 200, which has been activated by the low consumption standby power, reacts and the infrared control unit 600, the SMPS 400, The infrared switching unit 200 operates the main switch so that the power of the power supply unit 300 is supplied to the SMPS 400 and drives the SMPS 400 so that the infrared control unit 600 and the CPU 500, And the like are driven.

If the infrared signal signal processed by the CPU 500 is an on signal, the CPU 500 outputs a control signal to the infrared switching unit 200 and drives the main switch 230 of the infrared switching unit to supply power from the power source unit 300 So that the SMPS 400 is continuously energized.

That is, even if the infrared signal is lost from the remote controller after the user presses the remote controller, if the infrared signal processed by the CPU 500 already operated is an on signal, The SMPS 400 is continuously energized.

The terminal of the infrared ray receiving module of the present invention includes a terminal for inputting a signal to the B-plus terminal of the power supply unit 300 to a conventional terminal, a terminal for inputting a signal to the IR switching unit 200, 400 are output.

In the embodiment of the present invention, 5 pin terminals are used. However, those skilled in the art can configure Vcc and SMPSon terminals in common by replacing the Vcc power supply with the SMPSon power supply.

Hereinafter, the configuration and operation principle of the infrared ray switching unit of the infrared ray receiving module of the present invention will be described.

4 and 5 are views illustrating the operation principle of the infrared ray switching unit of the infrared ray receiving module according to the embodiment of the present invention.

4, the infrared switching unit 200 is provided with a high resistance 210 for reducing the power consumption of the power input from the power supply unit 300 to low standby power of about 0.01 W to 0.04 W .

The signal input unit 220 is connected to the diode 100 while receiving a power through the high resistance 210 and is activated, and outputs a signal when a sensing signal is input from the diode.

The buffer 240 amplifies the signal output from the signal input unit 220.

The illustrated first semiconductor switch 250 is triggered and driven by a signal output via the buffer 240.

The coil 230a constituting the main switch 230 is positioned between the power supply unit 300 and the first semiconductor switch 250 and is connected to the power supply unit 300 while the first semiconductor switch 250 is driven. Voltage is applied.

The contact 230b constituting the main switch 230 is operated by the coil 230a to turn on the power supply from the power supply unit 300 to the SMPS 400 and the SMPS 400 The voltage is also applied to the CPU 500 and the infrared ray control unit 600 through the bus line.

In the case of the present invention, although the main switch 230 is configured using a relay switch, it will be apparent to those skilled in the art that such a configuration can be configured through various semiconductor switches such as TR, FET, and the like.

Actually, the time that the user presses the remote control is not within the range of 0.3 seconds to 1 second. Therefore, when the infrared signal of the remote controller disappears, the trigger signal of the first semiconductor switch 250 disappears and the main switch 230 can no longer be operated.

5, when the infrared control unit 600 is activated while the Vcc voltage is applied to the SMPS 400 to receive the infrared signal of the remote controller, the infrared signal is generated and transmitted to the CPU 500 .

At this time, if the CPU 500 determines that the property of the infrared signal of the remote controller is the on signal, the CPU 500 is configured to transmit the control signal to the second semiconductor switch 260. Also, if the CPU 500 determines that the property of the infrared signal is an on signal, the CPU 500 activates a switch for applying a power voltage of the electric / electronic product.

The second semiconductor switch 260 is triggered by a control signal transmitted from the CPU 500 and is connected to the coil 230a of the main switch 200 and is continuously connected to the coil 230a from the power supply 300. [ Voltage is applied.

Accordingly, even when the infrared signal of the remote controller is lost while the contact of the main switch is continuously maintained in the ON state, the power of the power source is continuously supplied to the SMPS 400. [

As a result, the power voltage of the electric / electronic product is applied through the SMPS 400 to operate the electric / electronic product.

If the user presses the remote controller again to generate an off infrared signal in this state, the CPU 500 no longer transmits a control signal to the second semiconductor switch 260, so that the main switch 230 .

Accordingly, all the power sources of the SMPS 400, the CPU 500, and the infrared control unit 600 except for the infrared ray switching unit 200 are turned off, and the power of the electrical and electronic products is also turned off and returned to the initial state .

6 is a conceptual diagram of a time required for converting the power supply of the electric / electronic product into the on state through the infrared ray receiving module of the present invention.

In the case of the present invention, when the standby power of the infrared control unit 600, the SMPS 400 and the CPU 500 is blocked and the infrared switching unit 200 recognizes the remote control infrared signal, the infrared control unit 600 and the SMPS (400), the CPU (500), and the like are activated. Therefore, a problem of time delay may occur when a user presses a remote control to transmit an infrared signal and the electric / electronic product returns from an off state to an on state.

The infrared switching unit 200 of the present invention drives the SMPS 400 while receiving the sensing signal from the diode 100 and drives the infrared control unit 600 again to control the infrared control unit 600 The total time required for turning the power supply of the electrical and electronic equipment from off to on is 20 ms.

That is, power conversion of the electric / electronic product is performed within a time period of 0.3 seconds to 1 second, which is the time required for the user to press the remote controller, so that standby power can be obtained without additional time delay due to the addition of the infrared switching unit 200 There is an effect that can be minimized.

In the foregoing, the present invention has been described with reference to the preferred embodiments thereof with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings and the foregoing embodiments are provided by way of illustration for purposes of clarity of understanding to those skilled in the art to which the present invention pertains. It is, therefore, to be understood that the various embodiments of the present invention may be embodied in various forms without departing from the essential characteristics thereof, and the above-described embodiments are to be considered as illustrative and not restrictive. Accordingly, the scope of the present invention should be construed in accordance with the invention as set forth in the appended claims rather than the foregoing embodiments, and various changes, alternatives, and equivalents by those skilled in the art may be made by the inventions It is obvious that it is included in the range of.

100: Diode 200: Infrared switching unit
210: high resistance 220: signal input part
230: main switch unit 230a: coil
230b: contact point 240: buffer
250: first semiconductor switch 260: second semiconductor switch
300: Power supply unit 400: SMPS
500: CPU 600: Infrared control unit

Claims (4)

A remote control receiver module for an electric / electronic product, which receives an infrared signal of a remote controller and receives power supplied from a power supply unit through a SMPS,
A diode that is energized while receiving the infrared signal of the remote controller to output a detection signal;
A signal input unit connected to the diode and outputting a signal when a sensing signal is inputted from the diode while a high resistance that reduces the power consumption of the power source inputted from the power source unit and a power source having the high resistance are input and maintained active, A first semiconductor switch which is driven by being triggered by a signal outputted from the buffer through the buffer, and a second semiconductor switch which is located between the power supply and the first semiconductor switch while the first semiconductor switch is driven, An infrared switching unit including a coil to which a voltage is applied from a power supply unit and a main switch which is operated by the coil and has a contact for energizing power from the power supply unit to the SMPS;
An infrared control unit driven by receiving power from the energized SMPS to receive a sensing signal from the diode at the signal input unit and generating and outputting a signal processed infrared signal; And
And a CPU which is driven while receiving power from the SMPS and receives a signal-processed infrared signal output from the infrared control unit and determines an infrared signal,
When the infrared signal signal processed by the CPU is determined as an on signal, a control signal is output to the infrared switching unit to drive the main switch of the infrared switching unit to continuously supply power from the power supply unit to the SMPS. Infrared receiver module with standby power cut-off function. The method according to claim 1,
And a second semiconductor switch connected to the coil, the second semiconductor switch being triggered by a control signal output from the CPU while determining the infrared signal as an on signal,
And the second semiconductor switch is driven to continuously apply a voltage to the coil of the main switch from the power supply unit to maintain the contact of the main switch in an on state. The method according to claim 1,
Wherein the signal input unit of each of the infrared switching unit and the infrared control unit receiving the sensing signal from the diode has a parallel structure. delete

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