KR101564915B1 - Dust sensor monitoring apparatus and method for monitoring the same - Google Patents

Abstract

The dust sensor module of the present invention outputs a preset frequency to the determination module during the aging time when the power is supplied. The determination module receives the frequency and determines whether the dust sensor module is operated based on the input frequency, State.

When the dust sensor module outputs the preset first and second frequencies during the aging time, which is the stabilization time of the dust sensor module after power is applied, the determination module receives the first and second frequencies, It is possible to monitor the state of the dust sensor module more efficiently by judging more accurately and easily whether the power is applied, whether the dust sensor module operates normally, and whether the dust sensor module and the judgment module are connected or disconnected.

Description

[0001] Dust sensor monitoring apparatus and method [0002]

The present invention relates to a dust sensor monitoring apparatus and a method thereof, and more particularly, to a dust sensor monitoring apparatus and method for determining a driving state of a dust sensor.

The dust sensor is a sensor that senses dust in an air cleaner, an indoor and outdoor air quality sensing device and a soot detector of a vehicle exhaust and a vacuum cleaner, or senses floating dust (turbidity) floating in water and outputs an electrical signal. That is, the dust sensor detects the amount of light scattered by dust, and detects the amount or concentration of dust.

The output value of the dust sensor varies depending on the amount of dust in the air. Accordingly, since the output of the dust sensor is constant in a small space such as a clean room or a space with a certain degree of contamination, it is difficult to judge whether the dust sensor operates normally or not.

When the dust sensor is installed in the product, it is difficult to arbitrarily adjust the input value of the dust sensor to check the status of the dust sensor, so that the operation state and the connection state of the dust sensor can not be confirmed.

That is, when a high signal is continuously output from the dust sensor due to the output characteristics of the dust sensor, it is difficult to know whether the dust level is small or the power terminal (Vcc) and the output terminal of the dust sensor are short , And when a Low signal is continuously output from the dust sensor, it is noticed that the amount of dust is large and the output terminal of the dust sensor is disconnected, or the ground terminal (GND) and the output terminal are short-circuited.

According to an aspect of the present invention, there is provided a dust sensor module that outputs a preset frequency during an aging time when power is applied; And a determination module for determining a connection state with the dust sensor module and a normal operation of the dust sensor module based on the frequency inputted from the dust sensor module.

Here, the predetermined frequency is a first frequency and a second frequency which are different from each other.

The dust sensor module further includes a heating unit for generating convection, and the aging time is a heating standby time during which the heating unit is driven stably.

The dust sensor module further includes a first output unit for outputting a signal corresponding to whether or not dust is detected larger than a reference and a second output unit for outputting a signal corresponding to whether or not dust smaller than the reference is detected, The frequency and the second frequency are frequencies having different values.

According to another aspect of the present invention, the dust sensor module outputs a preset frequency to the determination module during the aging time when power is supplied, and the determination module senses the frequency and determines whether the dust sensor module operates based on the sensed frequency .

Here, sensing the frequency is to detect the first and second frequencies output from the dust sensor module.

The first and second frequencies are different frequencies outputted to different output portions of the dust sensor module, and the connection state with the dust sensor module is determined according to the first and second frequencies inputted to the judgment module .

The method further includes checking the power source, the first and second frequencies of the dust sensor module, and determining the connection state with the dust sensor module.

The aging time is the time from when the power is applied to the dust sensor module to when the dust sensor module is stably driven.

According to one aspect of the present invention, when the dust sensor module outputs preset first and second frequencies during the stabilization time of the dust sensor module after the power is applied, the determination module receives the first and second frequencies, The status of the dust sensor module can be efficiently monitored by judging whether the module is normally powered, whether the dust sensor module is operating normally, and whether the connection between the dust sensor module and the judgment module is disconnected or disconnected.

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

FIG. 1 is a configuration diagram of a dust sensor monitoring apparatus according to an embodiment of the present invention, which includes a dust sensor module 100 and a determination module 200.

The dust sensor module 100 includes a ground unit 110, a power supply unit 120, a rectifying unit 130, a microcomputer 140, a heating unit 150, a light emitting unit 160, a light receiving unit 170, 180 and a second output unit 190.

The ground unit 110 is a ground which serves as a path for flowing an abnormal current flowing through the dust sensor module 100 to the ground. The power unit 120 receives a power supply Vcc supplied from the outside, And the rectifying unit 130 rectifies the voltage Vcc of the power supplied from the power supply unit 120 to a voltage for driving each driving unit provided in the dust sensor module 100. [

The microcomputer 140 controls the driving of the heating unit 150 when the power is supplied from the rectifying unit 130 and the first output unit 180 during the aging time stabilized from the start of driving the heating unit 150 To output the first frequency f1 and controls the driving of the second output unit 190 to output the second frequency f2. The microcomputer 140 controls the driving of the light emitting unit 160 and the light receiving unit 170 according to an instruction from the determination module 200 and determines the size of the dust based on the signal inputted from the light receiving unit 170, And transmits the result to the determination module 200 through the first output unit 180 and the second output unit 190.

Here, when the power source is applied, the heating unit 150 generates heat and causes convection to occur within a few seconds, thereby moving the collected dust in front of the light receiving unit 170. The light emitting unit 160 generates light according to an instruction from the microcomputer 140 when power is applied thereto. The light emitting unit 160 uses a light emitting diode (LED) or a laser diode that emits infrared light.

When the light emitted from the light emitting unit is reflected by the dust, the reflected light enters the light receiving unit 170, generates a photocurrent corresponding to the incident light, outputs the photocurrent to an amplifying unit (not shown) Not shown) converts the photocurrent inputted from the light receiving unit 170 into a voltage and outputs the amplified waveform to the microcomputer 140.

The microcomputer 140 determines the size of the dust according to the photocurrent transmitted from the amplifying unit (not shown). The size of the dust is determined by the amount of light incident on the light receiving unit 170. The larger the dust is, the more light is reflected by the dust, so the amount of light incident on the light receiving unit 170 is increased , Resulting in a large photocurrent.

The first output unit 180 transmits a signal to the determination module 200 when particles larger than the reference are detected according to an instruction from the microcomputer 140. If the particles are not detected dust larger than the reference, And transmits a high signal to the module 200. The first output unit 180 outputs the first frequency f1 during the binary time of the dust sensor module in which the operation of the heating unit is stabilized from the moment when the operating power is applied in accordance with the instruction of the microcomputer 140. [

The second output unit 190 transmits a signal to the determination module 200 when particles smaller than the reference are detected in accordance with an instruction from the microcomputer 140. When the particle is smaller than the reference, And transmits a high signal to the module 200. The second output unit 190 outputs the second frequency f1 during the aging time of the dust sensor module 100 in which the operation of the heating unit 150 is stabilized from the time when the operating power is applied in accordance with the instruction of the microcomputer 140, .

The determination module 200 includes a ground sensing unit 210, a power sensing unit 220, a first input unit 230, and a second input unit 240.

The ground sensing unit 210 is connected to the ground unit 110 of the dust sensor module 100 and determines whether the ground unit 210 is disconnected, connected, or shorted according to a signal transmitted from the ground unit 110, The sensing unit 220 is connected to the power supply unit 120 of the dust sensor module 100 and determines whether the power supply unit 120 is normally operated, disconnected, connected, or shorted according to a signal transmitted from the power supply unit 120.

The first input unit 230 is connected to the first output unit 180 of the dust sensor module 100 and receives the first frequency from the first output unit 180. The first input unit 230 determines whether the microcomputer 140 is operating normally, And determines whether the module 100 is connected to the first output unit 180. The first output unit 180 receives a high or low signal according to whether the dust sensor is larger than the reference. The second input unit 240 is connected to the second output unit 190 of the dust sensor module 100 and receives the second frequency from the second output unit 180. The second input unit 240 determines whether the microcomputer 140 is operating normally, It is determined whether or not the second output unit 190 of the module 100 is connected to the first output unit 180 and the first output unit 180 receives a high or low signal according to whether the dust sensor is larger than the reference.

After the power is applied to the dust sensor monitoring device, it is determined whether the dust sensor module 100 is operating normally during the stabilization time (aging time) of the dust sensor module 100, and the determination module 200 and the dust sensor module 100, It is possible to easily and accurately judge whether or not the wiring of the wire with the wire is connected.

FIG. 2 is a monitoring flowchart of a dust sensor monitoring apparatus according to an embodiment of the present invention, which will be described with reference to FIGS. 3 and 4. FIG. 3 (a) shows the output waveform of the first frequency according to the time outputted from the first output unit, and FIG. 3 (b) shows the output waveform of the second frequency according to the time output from the second output unit. 4 is a voltage waveform output from each output unit depending on whether dust is detected or not.

First, when the dust sensor module 100 and the determination module 200 are initially powered on or when the power is applied (301) after the standby mode is released, the dust sensor module 100 and the determination module 200, Supplies operating power to each driving unit and drives each driving unit.

That is, when the operation power is applied through the power supply unit 120 of the dust sensor module 100, the rectifier 130 converts the voltage Vcc of the power supply unit 120 to the operation of each driving unit provided in the dust sensor module 100 The voltage is rectified to an appropriate voltage and supplied to each driver. At this time, when power is applied to the microcomputer 140 of the dust sensor module 100, the microcomputer 140 controls the driving of the heating unit 150 to generate convection so that the dust located in front of the light receiving unit 170 is moved, The operation of the first output unit 180 and the second output unit 190 is controlled to determine the operation state of the dust sensor module 100 and the wire connection.

3, the microcomputer 140 of the dust sensor module 100 controls the aging of the dust sensor module 100, in which the operation of the heating unit 150 is stabilized, The first frequency f1 is output through the first output unit 180 and the second frequency f2 is output through the second output unit 190 during the time T11 and T21. The dust data sensed by driving the light emitting unit 160 and the light receiving unit 170 during the waiting time of the heating unit 150 after the application of the power to the dust sensor module 100 is not reliable and is not used. Accordingly, the operation of the dust sensor module 100 and the connection or disconnection state between the dust sensor module 100 and the determination module 200 are determined during the heating wait time (i.e., the aging time) of the heating unit 150 .

That is, during the aging time, the ground sense unit 210 of the determination module 200 determines the connection state of the ground unit 110 based on the signal input from the ground unit 110 of the dust sensor module 100, The sensing unit 220 determines the connection state and the operation state of the power supply unit 120 based on a signal input from the power supply unit 120 of the dust sensor module 100.

The first input unit 230 of the determination module 200 receives the first frequency 303 from the first output unit 180 and receives the first frequency f1 from the first output unit 230 based on the input first frequency f1. The wire connection state, and the operation state of the first output unit 230 (step 304). That is, the first input unit 230 determines that the first frequency is not input, and determines that the wire is a short circuit (i.e., a short circuit) when the second frequency is input without the first frequency being input.

 The second input unit 240 of the determination module 200 receives the second frequency f2 input from the second output unit 190 and receives the second frequency f2 based on the input second frequency f2, (240) and the operation state of the second output unit (240). That is, when the second frequency f2 is not input, the second input unit 240 determines that the wire is a disconnection. When the first frequency f1 is input without the second frequency f2 input, (I.e., a short line).

When the first and second frequencies f1 and f2 are output from the respective outputs of the dust sensor module during the aging time after the power is turned on, the determination module 200 determines that the first and second frequencies f1 and f2 the normal operation of the dust sensor module 100 and the normal operation of the micom 140 of the dust sensor module 100 and the normal operation of the dust sensor module 100 and the determination module 200 ) Can be judged by electrical connection, disconnection or short-circuit.

Accordingly, when a high signal is continuously output from at least one output portion of the dust sensor module 100 due to an output characteristic of the dust sensor module 100, it is determined that no dust is detected, Vcc) and the corresponding output are shorted (i.e., short-circuited).

Also, when a low signal is continuously output from at least one output portion of the dust sensor module 100, a lot of dust is detected and the corresponding output portion is disconnected, so that the ground end GND and the corresponding output portion are short-circuited Can be accurately identified.

The output of the first and second output units 180 and 190 is stopped for a predetermined period of time T12 and T22 while the heating unit 150 is driven and the output of the dust sensor module 100 and the determination module 200 If it is determined that both the connection state and the operation state are normal, the operation of the first and second output units 180 and 190 during the dust detection time (T13, T23) of the outputs of the first and second output units 180 and 190 And outputs the first and second frequencies f1 and f2. The light emitting unit 160 is driven to generate light.

When the light emitted from the light emitting unit 160 is scattered by dust, the light receiving unit 170 receives the scattered light, generates a photocurrent corresponding to the incident light, and outputs the photocurrent to an amplifying unit (not shown). At this time, the amplifying unit (not shown) converts the inputted photocurrent into a voltage and outputs the amplified waveform to the microcomputer 140. The microcomputer 140 determines the size of the dust according to the photocurrent transmitted from the amplifying unit And transmits a signal corresponding to the determination result to the determination module 200 through the first output unit 180 and the second output unit 190.

4, when it is determined that there is no dust, the determination module 200 outputs the high signal V2 through the first output unit 180 and the second output unit 190, And outputs a signal V1 through the first output unit 180 or the second output unit 190 according to the dust size. That is, when dust larger than the reference is detected, the signal V1 is output through the first output unit 180 and the signal V1 is output through the second output unit 190 when dust smaller than the reference is detected. . Here, the size of the dust is determined by determining the size of the dust according to the amount of light incident on the light receiving unit 170 since the smaller the dust is, the more light is reflected by the dust. Here, the first and second output units 180 and 190 may output the PWM signal to the determination module 200 according to the amount of dust or output the PWM signal at the voltage level.

1 is a configuration diagram of a dust sensor monitoring apparatus according to an embodiment of the present invention.

2 is a flowchart of a monitoring method of a dust sensor monitoring apparatus according to an embodiment of the present invention.

3 is a frequency output waveform during the aging time of the dust sensor monitoring apparatus according to the embodiment of the present invention.

4 is a voltage output waveform according to dust detection of a dust sensor monitoring apparatus according to an embodiment of the present invention.

Description of the Related Art [0002]

100: Dust sensor module 110: Ground part

120: power supply unit 130:

140: Micom 150: Heating section

160: light emitting portion 170:

180: first output unit 190: second output unit

200: Judgment module 210: Ground sensing part

220: power detection unit 230: first input unit

240: second input section

Claims (9)

A first output unit for outputting a first frequency and a second output unit for outputting a second frequency that is different from the first frequency, wherein when the power is applied, the first frequency and the second frequency are outputted during the aging time Dust sensor module; A first input unit connected to the first output unit and a second input unit connected to the second output unit, wherein the first input unit and the second input unit check whether a frequency is input during the aging time, And a judging module for judging a connection state with the dust sensor module and a normal operation of the dust sensor module based on the type of the frequency inputted to the at least one input unit when a frequency is inputted to one input part, Device. 2. The apparatus of claim 1, A ground sensing unit for sensing a connection state with the ground unit based on a signal of the ground unit of the dust sensor module; And a power sensing unit for sensing a connection state with the power supply unit based on a signal of a power supply unit of the dust sensor module. The method according to claim 1, The dust sensor module may further include a heating unit for generating convection, Wherein the aging time is a heating standby time during which the heating unit stably drives. The method according to claim 1, Wherein the first output unit outputs a signal corresponding to whether or not dust is detected that is larger than a reference when dust is detected, Wherein the second output unit outputs a signal corresponding to whether or not dust is detected that is smaller than a reference value when the dust is detected. When the power is supplied to the dust sensor module, the first frequency is outputted through the first output portion provided in the dust sensor module during the aging time, Outputting a second frequency through a second output unit provided in the dust sensor module during the aging time, And a controller for checking whether the first frequency output from the first output unit and the second frequency output from the second output unit are input during the aging time, If at least one of the first frequency and the second frequency is inputted, the type of the input frequency is confirmed, And determining whether a connection state with the dust sensor module and a normal operation of the dust sensor module are established based on whether the first frequency and the second frequency are input and the type of the input frequency. The method of claim 5, wherein determining the connection state with the dust sensor module comprises: If it is determined that the first frequency is not input to the first input unit of the determination module, And determining that the second output has been disconnected if the second frequency is not input to the second input of the determination module. The method of claim 6, wherein determining the connection state with the dust sensor module comprises: Determines that the first input unit and the second output unit are shorted when it is determined that the second frequency is input to the first input unit of the determination module, Further comprising determining that the second input and the first output are shorted if it is determined that the first frequency is input to the second input of the determination module. 6. The method of claim 5, Detecting a connection state with the ground portion based on a signal of a ground portion of the dust sensor module during the aging time and detecting a connection state with the power supply portion based on a signal of a power supply portion of the dust sensor module Dust sensor monitoring method. 6. The method of claim 5, Further comprising driving the heating unit during the aging time, Wherein the aging time is a time from when power is applied to the dust sensor module to when the operation of the heating part is stably driven.

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