KR100732542B1 - Air cleaners and their pollution degree - Google Patents

Abstract

The present invention relates to an air purifier and a method of displaying a pollution level thereof. In the method of displaying a pollution level of an air cleaner displayed on a display unit by measuring a pollution level of indoor air in a gas sensor, the power is supplied to the gas sensor when the air cleaner is turned on. When the gas sensor is stabilized, the pollution level is not measured by the gas sensor, but when the gas sensor is stabilized, the pollution level of the indoor air is measured and displayed on the display unit.

Description

Air cleaner and method to display pollution level

1 is an exploded perspective view of an air cleaner according to an embodiment of the present invention.

2 is a block diagram showing a control configuration of an air cleaner according to an embodiment of the present invention.

3 is a flowchart illustrating a method for displaying pollution levels of the air cleaner shown in FIGS. 1 and 2.

4A and 4B illustrate changes in gas sensor output voltage during sensor stabilization period and contamination detection.

           * Description of the symbols for the main functions of the drawings *

                    23: gas sensor 24: dust sensor

                    26: display unit 27: input unit

                    30: Microcomputer

The present invention relates to an air cleaner and a method for displaying the pollution level, and more particularly, to an air cleaner and a method for displaying the pollution level by measuring and displaying a more accurate pollution level by minimizing the measurement of the pollution level in a state where the gas sensor is not stabilized. will be.

Generally, air purifier is a device that purifies polluted air and converts it into fresh air. In order to comfortably improve the environment of indoor or closed space, dust, odor, bacteria, tobacco smoke and volatile organic compounds (VOC) are used. Remove contaminants such as

Conventional air purifiers, as disclosed in Korean Patent Laid-Open Publication No. 1999-0066661, a key input unit for inputting a user's operation command, a gas detector for measuring a pollution level in a room, a blower fan, a dust collecting unit, and a sterilizing and deodorizing device, respectively. And a microcomputer for controlling the operation state of the load driving means according to the input of the key input unit and the degree of contamination of the room detected by the gas detection unit.

At this time, the gas sensor uses a semiconductor gas sensor. The semiconductor gas sensor detects the pollution level in the room by using the degree of change in the resistance value due to the amount of odor molecules adsorbed on the surface. In addition, such a reaction does not occur well at room temperature but occurs well at a temperature higher than room temperature. Therefore, in the conventional air cleaner, even if the power of the air cleaner is not turned on, if the air cleaner is connected to the power supply, the gas sensor is preheated by pre-heating the gas sensor when the air cleaner is connected to the power supply. The pollution degree of was measured and displayed.

However, such a conventional air cleaner has a problem in that unnecessary power is wasted because power is applied to the gas sensor even when the air cleaner is not turned on.

The present invention is to solve the above problems, an object of the present invention is to provide an air cleaner that applies power to the gas sensor only when the power is on.

Another object of the present invention is to provide an air purifier and a method for displaying the pollution level, which accurately measure and display the pollution level of indoor air even with a gas sensor that is not preheated.

The present invention for achieving the above object is a method of displaying a pollution degree of an air cleaner displayed on the display unit by measuring the pollution degree of the indoor air in the gas sensor, when the power of the air cleaner is turned on, the power is applied to the gas sensor, Before the gas sensor is stabilized, the pollution degree is not measured by the gas sensor, but when the gas sensor is stabilized, the pollution degree of indoor air is measured by the gas sensor, and then displayed on the display unit.

In addition, the gas sensor is a semiconductor type gas sensor, and even if the semiconductor gas sensor is stabilized after the output voltage of the semiconductor type gas sensor even before it is stabilized after the cause, the degree of contamination is measured and displayed on the display unit. .

In addition, in the air cleaner having a gas sensor for measuring the pollution level of the indoor air, the display unit for displaying the pollution degree, and the microcomputer for controlling the pollution degree measured by the gas sensor to be displayed on the display unit, the micom is the air cleaner When the power is turned on, the power is applied to the gas sensor, and when the gas sensor is stabilized, the display unit controls the pollution degree of the indoor air measured by the gas sensor to be displayed.

In addition, the gas sensor is a semiconductor gas sensor, and the microcomputer corresponds to the output voltage of the semiconductor gas sensor when the output voltage of the semiconductor gas sensor drops and then rises even before the micro gas is stabilized after being applied to the semiconductor gas sensor. It characterized in that the control to display the pollution degree in the display.

In addition, the microcomputer determines that the output voltage of the gas sensor is stabilized when it is maintained within a specific voltage range after rising and falling.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the air cleaner according to an embodiment of the present invention includes a main body 10 and a front panel 11 detachably coupled to the main body 10. The front panel 11 is provided with a plurality of suction ports 12 formed long in the horizontal direction to introduce indoor air into the main body.

At the rear of the front panel 11, a prefilter 13 is detachably mounted to the main body 10. The prefilter 13 filters the large particles existing in the air sucked through the inlet 12, for example, impurities such as agglomerated dust and lint.

At the rear of the prefilter 13, a photocatalyst filter unit 14 which is activated by ultraviolet rays and performs sterilization and deodorization functions is provided. The photocatalyst filter unit 14 constitutes a front portion and a rear portion of the photocatalyst filter unit 14, respectively, and the front photocatalyst filter 15 and the back photocatalyst filter (coated with photocatalyst, for example, titanium dioxide (TiO2)) are formed on the filter paper. 16). In addition, the front photocatalyst filter 15 and the back photocatalyst filter 16 are coupled to the front and rear surfaces of the coupling frame 17 having a rectangular shape, respectively. Ultraviolet lamp mounting members 18 are provided on upper and lower inner surfaces of the coupling frame 17, and a plurality of ultraviolet lamps 19 are inserted into the ultraviolet lamp mounting members 18 in the vertical direction. The ultraviolet lamp 19 is installed for the excitation of each photocatalyst filter 15, 16. When the ultraviolet lamp 19 is turned on and the ultraviolet light is irradiated to each photocatalyst filter 15, 16, the oxidation reaction of the photocatalyst occurs to sterilize and deodorize. The function is performed.

The rear side of the photocatalyst filter unit 14 is provided with a fine filter 20 for filtering out fine impurities. The fine filter 20 removes impurities such as dust that are several micrometers or less.

The rear part of the main body 10 is provided with a blowing fan 21 for forcibly circulating the air to be discharged to the outside of the main body 10 after the indoor air is introduced into the main body and purified. A plurality of discharge ports 22 formed long in the horizontal direction are provided in the upper rear of the main body 10 to discharge the purified air to the outside of the main body.

A gas sensor 23 for detecting an odor present in indoor air and a dust sensor 24 for detecting dust are installed on an upper portion of the front surface of the main body 10. At this time, the gas sensor 23 is a semiconductor gas sensor, the semiconductor gas sensor is characterized in that the resistance value of the semiconductor is changed when the odor molecules existing in the indoor air is adsorbed on the surface, thereby changing the output voltage. More specifically, the more odor molecules present in indoor air, the higher the output voltage of the semiconductor gas sensor, and the less odor molecules present in indoor air, the lower the output voltage of the semiconductor gas sensor. Therefore, if the output voltage of the semiconductor gas sensor is grasped, the pollution level of indoor air can be known.

 The front panel 11 is provided with a protection net 25 for protecting the gas sensor 23 and the dust sensor 24 at a position corresponding to the gas sensor 23 and the dust sensor 24 installed in the main body 10. . An upper portion of the main body 10 is provided with an input portion 27 for inputting an operation signal by the user and a display portion 26 for displaying an operation state of the air cleaner.

In this embodiment, the gas sensor 23 and the dust sensor 24 are disposed on the front surface of the main body 10, but the gas sensor 23 and the dust sensor 24 are easily positioned in contact with indoor air. For example, around the display unit 26 and the input unit 27).

As shown in FIG. 2, the air cleaner according to the exemplary embodiment of the present invention drives the blower fan motor 32 and the blower fan motor 32 that rotate the blower fan 21 in addition to the components shown in FIG. 1. In addition to the fan motor driving unit 31, the lamp driving unit 33 for driving the ultraviolet lamp 19, and the degree of pollution corresponding to the output voltage of the gas sensor 23 is displayed on the display unit 26, The microcomputer 30 further controls the overall operation.

Referring to Figure 3 will be described a pollution degree display method of an air cleaner according to an embodiment of the present invention. When the user presses the power button of the input unit 27 to turn on the air cleaner 40, the microcomputer 30 allows power to be applied to the gas sensor 23 (42). When power is applied to the gas sensor 23, the gas sensor 23 enters a sensor stabilization mode. In the sensor stabilization mode, the output voltage of the gas sensor 23 is increased once (initial characteristic) and then decreased to be maintained in a specific voltage range (stabilization characteristic). Therefore, the microcomputer 30 determines that the output voltage of the gas sensor 23 is stabilized when the output voltage is maintained in the rising-falling-specific voltage range after the power is applied. At this time, the specific voltage range may vary depending on the gas sensor 23, and in this embodiment, it is regarded as about 2-3V.

The microcomputer 30 checks the output voltage of the gas sensor 23 to determine whether the gas sensor 23 is stabilized (44), and if the gas sensor 23 is stabilized, the pollution degree corresponding to the output voltage of the gas sensor 23 is determined. Is displayed on the display unit (48). To this end, the microcomputer 30 has a value of pollution degree corresponding to the output voltage of the gas sensor 23 in advance.

In FIG. 4A, the sensor stabilization period and the output voltage of the gas sensor 23 that are different at the time of detecting the pollution when detecting the pollution after the gas sensor is stabilized are illustrated (X-axis: time, Y-axis: voltage). As shown in FIG. 4A, when power is applied to the gas sensor 23, the output voltage of the gas sensor 23 rises to 5V (initial characteristic) and then gradually decreases, and then remains in the voltage range of 2V-3V (stabilization characteristic). Stabilized. When the output voltage of the gas sensor 23 rises beyond the sensor stabilization period (A), the output voltage of the gas sensor is increased by the odor molecules in the indoor air, and thus the pollution level corresponding to the output voltage is displayed. To display.

On the other hand, if it is determined in step 44 that the output voltage of the gas sensor 23 is not stabilized, the microcomputer 30 does not maintain the specific voltage range after the output voltage of the gas sensor 23 rises and falls again and then rises again. Judgment (46). If the output voltage of the gas sensor 23 rises and then rises again, the output voltage of the gas sensor 23 is considered to have risen by the odor molecules in the indoor air, and thus the pollution level corresponding to the output voltage is displayed. To display. However, if the condition of step 46 is not satisfied, the gas sensor 23 is not yet stabilized, and thus the contamination level is not displayed on the display unit 26.

In FIG. 4B, the output voltage of the gas sensor 23, which is different at the time of detecting the sensor stabilization period and the pollution degree when detecting the pollution degree before the gas sensor is stabilized, is shown (X axis: time, Y axis: voltage). As described above, when power is applied to the gas sensor 23, the output voltage of the gas sensor 23 rises to 5V (initial characteristic) and then gradually decreases, and even before the gas sensor 23 stabilizes, the gas is released by the odor molecule. The output voltage of the sensor 23 may rise again. In this way, if the output voltage of the gas sensor rises again even before the gas sensor stabilizes (B), the output voltage of the gas sensor rises due to the odor molecules in the indoor air, and thus the pollution level corresponding to the output voltage is displayed. To display.

As described in detail above, the present invention can prevent unnecessary waste of power consumption by applying power to the gas sensor only when the air purifier is turned on.

In addition, it is possible to minimize the display of inaccurate pollution by the gas sensor not preheated during operation of the air cleaner.

Claims (5)

delete In the method of displaying the pollution level of the air cleaner displayed on the display unit by measuring the pollution level of the indoor air in the semiconductor gas sensor, When the power of the air cleaner is turned on, the power is applied to the semiconductor gas sensor, Determining the stabilization of the semiconductor gas sensor by sensing the output change of the semiconductor gas sensor, When the output voltage of the semiconductor gas sensor drops and rises even after the semiconductor gas sensor is turned on and stabilized, the display unit displays a pollution degree corresponding to the output voltage of the semiconductor gas sensor on the display unit. Labeling delete  In an air purifier including a semiconductor gas sensor for measuring the pollution of indoor air, a display unit for displaying the pollution degree, and a microcomputer for controlling the pollution degree measured by the semiconductor gas sensor to be displayed on the display unit, The microcomputer applies power to the semiconductor gas sensor when the air purifier is turned on, and detects a change in output of the semiconductor gas sensor to determine whether the semiconductor gas sensor is stabilized. The microcomputer controls the display to display the pollution degree corresponding to the output voltage of the semiconductor gas sensor when the output voltage of the semiconductor gas sensor drops and then rises even before the semiconductor gas sensor is turned on and stabilized. Featured Air Purifier The method of claim 4, wherein The microcomputer determines that the output voltage of the semiconductor gas sensor is stabilized if the output voltage of the semiconductor gas sensor rises and falls and then remains within a specific voltage range.

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