KR101796298B1 - Ultraviolet air sterilizer and method of ultraviolet air sterilization - Google Patents

Abstract

According to an embodiment of the present invention, an ultraviolet (UV) air sterilizer comprises: a housing having a flow path to allow air to flow through; a blower fan provided on the flow path; an UV lamp provided in the housing and emitting UV light to air flowing in the flow path; an analysis module provided in the housing and measuring air condition so as to calculate a food poisoning risk coefficient; and a control module provided in the housing and controlling a degree of air sterilization based on the food poisoning risk coefficient.

Description

TECHNICAL FIELD [0001] The present invention relates to an ultraviolet air sterilizer and an ultraviolet air sterilizer,

The following examples relate to an ultraviolet air sterilizer and an ultraviolet sterilization method for sterilizing air by a UV lamp.

2. Description of the Related Art In recent years, there has been an increasing interest in supplying clean air to the room due to various environmental pollution. BACKGROUND ART [0002] In general, an ultraviolet air sterilizer is widely known, in which room air flows into the inside of the room, and ultraviolet rays are irradiated to the air to be sterilized by sterilizing various pathogenic microorganisms present in the air.

In particular, various microorganisms present in the air are mixed with food or drinks to generate toxins which cause food poisoning. Such food poisoning can be quantified by the possibility of food poisoning depending on factors such as air pollution, temperature, and humidity.

Therefore, a device or a method is needed to prevent food poisoning through air sterilization by judging the food poisoning index considering various factors in the air.

Regarding this, Registration Utility Model No. 20-0357824 discloses an air purifier using a photocatalyst.

An object of an embodiment is to provide an ultraviolet air sterilizer for analyzing the air condition to determine a food poisoning risk index.

An object of an embodiment is to provide an ultraviolet air sterilizer that controls the operation of a blowing fan or a UV lamp according to circumstances to control the degree of air sterilization.

An object of an embodiment is to provide an ultraviolet air sterilizer that changes the passage through which air passes and regulates the time the air stays in the passage.

An object of an embodiment is to provide a method of controlling air sterilization of an ultraviolet air sterilizer by determining the food poisoning risk index.

According to an embodiment of the present invention, there is provided an ultraviolet air sterilizer including a housing having a flow path for air to flow, a blowing module provided on the flow path, a UV lamp module provided in the housing to emit ultraviolet rays to air flowing through the flow path, An analysis module for measuring a food poisoning risk index by measuring an air condition and a control module provided in the housing for controlling the degree of sterilization of the air according to the food poisoning risk index.

On one side, the analysis module may include a temperature sensor and a humidity sensor.

In one aspect, the analysis module may further include an operation unit for calculating a food poisoning risk index by comparing the food poisoning index previously input based on the data measured by the temperature sensor and the humidity sensor.

On one side, the ultraviolet air sterilizer may further comprise a display indicating the measured data and the food poisoning risk index.

In one aspect, the control module may adjust the air blowing speed of the blow module or adjust the ultraviolet emission intensity of the UV lamp module according to the food poisoning risk index calculated by the analysis module.

The control module controls the ultraviolet emission intensity of the UV lamp module to be strongly controlled when the air blowing speed of the air blowing module becomes high and when the air blowing speed of the air blowing module is low, The intensity of ultraviolet radiation can be controlled to be weak.

On one side, the flow path is formed so that the path can be changed, so that the time during which the air stays in the flow path can be adjusted.

In one aspect, the control module may change the path of the flow path according to the food poisoning risk index calculated by the analysis module.

The ultraviolet air sterilizer may further include a communication module connected to the management server that performs the management service based on the home network and receives the information from the analysis module and transmits the information to the management server .

A method of controlling an ultraviolet air sterilizer according to an embodiment of the present invention includes the steps of providing an ultraviolet air sterilizer having a blowing fan and a UV lamp, measuring the temperature and humidity of the indoor space, And controlling the operation intensity of the blower fan and the UV lamp according to the food poisoning index.

According to one embodiment, the air condition can be analyzed to determine the food poisoning risk index.

According to one embodiment, the degree of air sterilization can be controlled according to the food poisoning risk index.

According to one embodiment, it is possible to control the degree of air sterilization by controlling the operation of a blowing fan or a UV lamp of an ultraviolet air sterilizer according to circumstances.

According to one embodiment, the passage through which the air passes can be changed to control the time the air stays in the ultraviolet air sterilizer.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, It should not be construed as limited.
1 is a perspective view illustrating an ultraviolet air sterilizer according to an embodiment.
2 is a block diagram showing the configuration of an ultraviolet air sterilizer according to an embodiment.
FIG. 3 is a flowchart showing the operation of the ultraviolet air sterilizer according to one embodiment.

Hereinafter, embodiments will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference numerals even though they are shown in different drawings. In the following description of the embodiments, detailed description of known functions and configurations incorporated herein will be omitted when it may make the best of an understanding clear.

In describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

First, the configuration of the ultraviolet light sterilizer 1 according to the embodiment will be described with reference to Figs. 1 and 2. Fig. FIG. 1 is a perspective view showing an ultraviolet air sterilizer 1 according to an embodiment, and FIG. 2 is a block diagram showing a configuration of an ultraviolet air sterilizer 1.

The ultraviolet air sterilizer 1 includes a housing 10, an air flow path formed in the housing 10, a blowing module 11 provided on the flow path, a UV (ultraviolet) Ultraviolet lamp module 12 as shown in FIG.

The ultraviolet air sterilizer 1 includes an analysis module 13 for measuring the air condition and calculating a food poisoning risk index based on the air condition and an ultraviolet air sterilizer 1 based on the data derived by the analysis module 13, And a control module 14 for controlling the degree to which air is sterilized.

 The housing 10 is provided with an inner space for accommodating various kinds of equipment therein. Various kinds of equipment and parts for operating the ultraviolet light sterilizer 1 may be located in the internal space.

In addition, the housing 10 can be manufactured in various shapes. For example, the shape of the housing 10 may be a polygonal column, a cylinder, or a cylindrical shape. However, the shape shown in the drawings is merely an example, and the shape of the housing 10 is not limited thereto.

The housing 10 may be formed with an air inlet 102 and an air outlet 103 through the outer surface of the housing 10 so that external air can flow into the housing 10. In this case, the air inlet 102 and the air outlet 103 may be formed at various positions of the housing 10. For example, the air inlet 102 and the air outlet 103 may be formed at both ends of the housing 10, respectively.

A flow path 101 for flowing the air introduced into the ultraviolet light sterilizer 1 from the air inlet 102 to the air outlet 103 may be formed in the housing 10. That is, the air can flow inside the ultraviolet air sterilizer 1 through the flow path 101.

In this case, the ultraviolet air sterilizer 1 may be provided with the flow path module 100 to change the flow path 101. The flow path module 100 can change the path of air passing through the flow path 101 and adjust the time during which the air stays in the flow path 101. [

For example, the flow path module 100 may change the path through which the air passes through the partition, or may have a separate auxiliary flow path so that air passing through the flow path 101 passes through the auxiliary flow path. In this case, the flow path module 100 may be provided with a flow control circuit, a motor, or the like for controlling the flow path 101 to change.

The air blowing module 11 is provided on the flow path 101 and can control the flow rate of the air passing through the flow path 101. At this time, the air blowing module 11 can adjust the air blowing speed in various ways.

For example, the blowing module 11 may include a blowing fan 111. In this case, the blowing fan 111 can be located on the flow path 101, and the blowing module 11 rotates the blowing fan 111 so that air flows into the air inlet 102, And then discharged to the air outlet 103.

In addition, the air blowing module 11 may include a plurality of air blowing fans 111 provided at various positions on the flow path 101. For example, the air blowing fan 111 is provided in each of the air inlet 102 and the air outlet 103 so that air can be blown through the air passage 101 and provided in the air passage 101.

The blowing module 11 may include a motor for rotating the blowing fan 111 and a blowing control circuit for controlling the rotational speed of the blowing fan 111. [

In particular, by controlling the rotational speed of the blowing fan 111, the blowing module 11 can adjust the speed at which air passes through the ultraviolet air sterilizer 1. Specifically, when the flow of the fast air is required, the speed of the blowing fan 111 may be increased, and in the opposite case, the speed of the blowing fan 111 may be decreased to control the flow rate of the air.

The UV lamp module 12 is provided inside the housing 10 and can sterilize the air passing through the ultraviolet air sterilizer 1. The UV lamp module 12 may include at least one UV lamp 121. The UV lamp 121 irradiates the air passing through the flow path 101 with ultraviolet rays to sterilize the air have.

The UV lamp 121 can be arranged in various ways. For example, as shown in the figure, the UV lamp 121 may be disposed in the middle of the flow path 101 through a clip provided on the wall surface of the flow path 101. [ In this case, since the UV lamp 121 emits ultraviolet rays in all directions, the air passing through the flow path 101 can be uniformly sterilized.

However, the arrangement of the UV lamp 121 shown in the drawings is merely an example, and the manner of disposing the UV lamp 121 is not limited thereto. For example, the UV lamp 121 may be arranged in the longitudinal direction on the wall surface of the flow path 101 to sterilize the air passing through the flow path 101.

In addition, a plurality of UV lamps 121 may be disposed in parallel with the wall surface of the flow path 101 to sterilize air. In this case, since the irradiation amount of ultraviolet rays to the same area increases, strong sterilization is possible at the same time.

The UV lamp module 12 may supply power to the UV lamp 121 and may include a control circuit for adjusting the ultraviolet emission intensity of the UV lamp 121.

Accordingly, the UV lamp module 12 can control the operation of the UV lamp 121 or the intensity of ultraviolet emission so as to control the degree to which the UV lamp 121 sterilizes the air. Specifically, when the pollution degree of the air passing through the ultraviolet air sterilizer 1 is high, the intensity of the UV lamp 121 is strongly controlled to effectively sterilize the air. When the pollution degree of the air is low, So that it is possible to prevent power waste due to the unnecessary operation of the UV lamp 121. [

The analysis module 13 is provided in the housing 10 to measure the air condition and calculate the food poisoning risk index based on the measured air condition.

The analysis module 13 may include various sensors for measuring the air condition. For example, the analysis module 13 may include a pollution detection sensor 130 for detecting the pollution degree of indoor air.

In this case, the pollution detection sensor 130 can detect various pollutants contained in the air. For example, the contamination detection sensor 130 may detect various kinds of volatile organic compounds (VOCs) such as a fine dust concentration in a space, a sulfur dioxide gas, carbon monoxide, nitrogen dioxide, ozone, a formaldehyde (HCHO), a toluene, benzene, ), Microorganisms such as nitrogen dioxide generated from asbestos, carbon dioxide (CO2), dust, cigarette smoke, odor and microbial materials (Escherichia coli, Pseudomonas aeruginosa, 0-157, Salmonella) and volatile organic pollutants, Other odors, noise, and radiation can be detected.

In addition, the analysis module 13 may further include various sensors for measuring the air condition. For example, it may further include a temperature sensor 131 and a humidity sensor 132 that measure the air temperature and humidity of the place where the ultraviolet light sterilizer 1 is installed in real time

The analysis module 13 may include an operation unit 135 for analyzing the air pollution degree based on the air condition measured by the pollution detection sensor 130, the temperature sensor 131, the humidity sensor 132, and the like.

The calculating unit 135 can calculate the food poisoning risk index of the air in comparison with the previously-input food poisoning index based on the air condition measured by the sensor. For example, it may contain data provided by the Food and Drug Administration (MFDS). Here, the Food and Drug Administration (MFDS) calculates the index of food poisoning based on the temperature and humidity of the air and provides it as a food poisoning index.

The operation unit 135 can compare the air condition at the point where the ultraviolet air sterilizer 1 is installed using the food poisoning index provided by the Food and Drug Administration (MFDS), and calculate the food poisoning risk index .

The calculation unit 135 compares the data on the pollutants detected by the pollution detection sensor 130 with the data provided by the national air pollution information management system (NAMIS), Air Korea, the Korea Meteorological Administration, The pollution index of the air condition can be calculated.

The analysis module 13 can transmit the measured air condition data and the calculated food poisoning risk index to the control module 14.

The control module 14 is provided inside the housing 10 and can control the degree to which the ultraviolet air sterilizer 1 sterilizes the air based on the data received from the analysis module 13.

The control module 14 can adjust the speed at which the air blowing module 11 blows air according to the food poisoning risk index. For example, when the food poisoning risk index is high, the air blowing module 11 can quickly control the air blowing speed, so that the air sterilizing speed can be controlled quickly.

That is, the rotational speed of the blowing fan 111 can be controlled to increase the amount of air flowing through the air sterilizer 1, thereby sterilizing a large amount of air for a unit time.

On the other hand, when the food poisoning risk index is low, the air blowing module 11 controls the air blowing speed to be slow, thereby preventing unnecessary power consumption and maintaining a constant air condition.

The control module 14 can adjust the degree to which the UV lamp module 12 irradiates ultraviolet rays to the air according to the food poisoning risk index. That is, when the food poisoning risk index is high, the UV lamp 121 strongly emits ultraviolet rays to increase air disinfection power, and when the food poisoning risk index is low, the ultraviolet emission intensity of the UV lamp 121 is lowered to prevent unnecessary power consumption .

Also, the control module 14 can control the air sterilization of the ultraviolet air sterilizer 1 by operating and controlling the flow path module 100 according to the food poisoning risk index. For example, by changing the flow path 101 to a longer length, it is possible to increase the time during which the air stays in the flow path 101, thereby increasing the time the air is irradiated with the ultraviolet rays from the UV lamp 121.

On the other hand, by shortening the flow path 101, it is possible to reduce the time that air stays in the flow path 101, and to allow a large amount of air to pass through the ultraviolet light sterilizer 1 per unit time.

As such, the process of controlling each module by the control module 14 can be executed individually or simultaneously.

For example, since the food poisoning risk index is high and the air flow rate of the air blowing module 11 is increased, the time required for the air to irradiate the ultraviolet rays is reduced, So that the degree of air sterilization can be kept constant.

On the other hand, when the food poisoning risk index is low, the air flow rate by the air blowing module 11 is lowered and the time for air to be irradiated with the ultraviolet rays is increased, By reducing the intensity, unnecessary power dissipation can be prevented.

In addition, it is possible to maximize the air sterilization efficiency of the ultraviolet light sterilizer 1 by executing the process of changing the path of air passing through the flow path 101 at the same time. That is, when the food poisoning index of the air is very high, the output of the air blowing module 11 is increased to speed up the flow of air, the intensity of ultraviolet emission of the UV lamp module 12 is increased, It is possible to increase the time for the air to be irradiated with ultraviolet rays by changing the flow path 101 to a long length.

 On the other hand, when the food poisoning index of the air is low, it is possible to execute only the respective module control or configure the operation intensity of each module to be reduced so as to prevent power waste and maintain a constant air condition.

As described above, the control of the degree of air sterilization by the control module 14 is possible according to the food poisoning risk index, but it is also possible by the separate air pollution index. For example, when the concentration of contaminants such as microorganisms measured by the analysis module 13 is high, air sterilization can be controlled by the control module 14 as described above.

Then, the control module 14 not only controls the ultraviolet light sterilizer 1 by monitoring the air condition in real time, but also measures various factors such as space, time, and season, It is possible to classify the respective classes according to the classification, and to control the air sterilization differentially according to the classified class.

In addition, the control module 14 may set whether to start the operation of the ultraviolet light sterilizer 1 according to the analysis result of the air condition, and may set and operate the operation duration time. Alternatively, the control module 14 may directly control the operation of the ultraviolet air sterilizer 1 and may transmit the information to the communication module 16 to allow the user to operate only the ultraviolet air sterilizer 1 It can play a role of providing.

The ultraviolet light sterilizer 1 may further include a communication module 16 provided in the housing 10 and capable of communicating with an external server.

The communication module 16 receives the information from the analysis module 13 and can transmit information on the air condition measured by the analysis module 13 to the external server. In this case, the external server may be the management server 500 that performs the management service based on the home network.

The communication module 16 receives the control information for the control module 14 through the management server 500 and provides the control information to the control module 14. The control module 14 controls the ultraviolet air The degree to which the sterilizer 1 sterilizes the air can be controlled.

In addition, the communication module 16 can communicate with a mobile device such as a smart phone or a tablet PC used by a user, or a mobile device including a PC. In this case, when the operation of the ultraviolet air sterilizer 1 is required, the user can be informed to generate a warning or an alarm, and the user can remotely control the operation of the ultraviolet air sterilizer 1 .

The ultraviolet light sterilizer 1 may further include a display 15 for displaying various information including operation information of the ultraviolet light sterilizer 1. [

The display 15 may be provided on the outer surface of the housing 10 to provide information to the user and may be located at one side of the housing 10 as shown in the figure. However, the positions shown in the drawings are merely illustrative, and may actually be located at various positions of the housing 10. [

The display 15 may display the current air condition measured by the analysis module 13. For example, the display 15 may display a variety of information such as current air temperature, humidity, air pollution index, food poisoning risk index, and the like.

Further, it is possible to display the operating state of the ultraviolet light sterilizer 1 at present. That is, the operation information including the blowing speed of the blow module 11, the ultraviolet emission intensity of the UV lamp module 12, the path of the air flow path 101, and the like can be displayed to the user.

In addition, the display 15 may generate a predetermined notification or an alarm when a notification according to the current air condition is required.

3 is a flowchart showing a process of controlling air sterilization according to the food poisoning index in the ultraviolet light sterilizer 1.

First, an air flow path is formed, and an ultraviolet air sterilizer 1 having a blowing fan 111 and a UV lamp may be provided. The blowing fan 111 controls the speed at which the air is introduced into the ultraviolet air sterilizer 1 and the UV lamp 121 can control the intensity of sterilizing the air introduced into the ultraviolet air sterilizer 1.

In the measuring step 201, the air condition at the point where the ultraviolet light sterilizer 1 is installed is measured. For example, in the measuring step 201, the temperature and humidity of the air can be measured. However, in addition to temperature and humidity, air pollution can be measured.

(VOCs) such as formaldehyde (HCHO), toluene, benzene, and acetone, nitrogen dioxide (NO 2) generated from asbestos (CO, CO, O-157, Salmonella) and volatile organic pollutants, other odors, noise, radiation, etc. in various kinds of household goods such as carbon dioxide (CO2), dust, Of indoor pollutants can be measured.

In the food poisoning index calculation step 202, the food poisoning risk index can be calculated based on the air condition data measured in the measurement step 201. The food poisoning risk index can be calculated based on information provided through communication with an external server or using pre-input data.

For example, the Food and Drug Administration (MFDS) has a food poisoning index based on air humidity and temperature. Therefore, it is possible to estimate the current food poisoning risk index based on the air condition data measured in the ultraviolet air sterilizer (1).

In the air sterilization control step 203, it is possible to control the degree to which the ultraviolet air sterilizer 1 sterilizes air according to the food poisoning risk index calculated.

For example, when the food poisoning risk index is high, the rotational speed of the air blowing fan 111 is increased to increase the flow rate of the air passing through the ultraviolet air sterilizer 1 for a unit time to sterilize a large amount of air, When the index is low, the rotating speed of the blowing fan 111 is lowered, and unnecessary power consumption can be prevented.

The intensity of ultraviolet emission of the UV lamp 121 can be controlled to control the degree of air sterilization for a unit time. In other words, when the food poisoning risk index is high, the power of the UV lamp is increased to increase the sterilizing power by the ultraviolet rays, and when the food poisoning risk index is low, the output of the UV lamp 121 is reduced and unnecessary power waste and a constant air condition can be maintained have.

It is also possible to perform control to change the flow path so as to adjust the time that air passing through the ultraviolet light sterilizer 1 stays in the ultraviolet light sterilizer 1. That is, a control for changing the length of the flow path according to the food poisoning risk index to increase the time for the air to stay inside the ultraviolet air sterilizer 1, or to shorten the flow path to reduce the time for the air to stay inside the ultraviolet air sterilizer 1 It is possible.

Such air sterilization control may be performed separately, and each control may be executed in combination.

According to the embodiments described above, the ultraviolet light sterilizer 1 can measure the air condition in real time and analyze the air pollution degree. Especially, it is possible to calculate the food poisoning risk index by analyzing the food poisoning index according to the air condition.

In addition, it is possible to scientifically air sterilize by utilizing measurement data obtained from sensors, basic data by external data, and the like.

Each module of the ultraviolet light sterilizer 1 can be controlled according to the food poisoning risk index or the degree of air pollution.

For example, when the sterilization of air is required to be high, the sterilizing power of the ultraviolet light sterilizer 1 is increased by raising the air blowing speed and ultraviolet radiation intensity and increasing the length of the channel 101, Life can be made possible.

On the other hand, when the need for sterilization of air is low, it is possible to lower the air blowing speed and ultraviolet radiation intensity, to shorten the flow path, to keep the air condition constant, and to prevent unnecessary power wastage.

In addition, the calculated food poisoning risk index or the operation state of the ultraviolet light sterilizer 1 can be displayed on the display, so that the user can conveniently manage the indoor air. In other words, satisfaction can be improved through communication with customers.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. For example, it is contemplated that the techniques described may be performed in a different order than the described methods, and / or that components of the described structures, devices, and the like may be combined or combined in other ways than the described methods, Appropriate results can be achieved even if they are replaced or replaced.

Therefore, other implementations, other embodiments and equivalents to the claims are within the scope of the following claims.

1: Ultraviolet air sterilizer
10: Housing
101: Euro
11: blowing module
111: blowing fan
12: UV lamp module
121: UV lamp
13: Analysis module
14: Control module

Claims (10)

A housing in which a flow path is formed to allow air to flow;
A blowing module provided in the flow passage for blowing air;
A UV lamp module which is provided in the housing and emits ultraviolet rays to air flowing through the flow path;
An analysis module provided in the housing for calculating a food poisoning risk index; And
And a control module provided in the housing for controlling the degree of sterilization of the air according to the food poisoning risk index,
The control module includes:
When the air blowing speed of the air blowing module is increased, the ultraviolet radiation intensity of the UV lamp module is strongly controlled,
Wherein the ultraviolet radiation intensity of the UV lamp module is weakly adjusted when the air blowing speed of the air blowing module is low.
The method according to claim 1,
Wherein the analysis module comprises a temperature sensor and a humidity sensor.
3. The method of claim 2,
Wherein the analysis module further includes an operation unit for calculating a food poisoning risk index by comparing the food poisoning index with a previously entered food poisoning index based on the data measured by the temperature sensor and the humidity sensor.
The method of claim 3,
An ultraviolet air sterilizer further comprising a display indicating the measured data and the food poisoning risk index;
The method according to claim 1,
Wherein the control module adjusts an air blowing speed of the blow module or adjusts an ultraviolet emission intensity of the UV lamp module according to a food poisoning risk index calculated by the analysis module.
delete The method according to claim 1,
The flow path is formed so that the path can be changed, and an ultraviolet air sterilizer capable of adjusting the time the air stays in the flow path as the flow path is changed,
8. The method of claim 7,
Wherein the control module changes the path of the flow path according to the food poisoning risk index calculated by the analysis module.
The method according to claim 1,
Further comprising a communication module communicably connected to a management server that performs a management service based on a home network and configured to receive information from the analysis module and transmit the information to the management server,
Providing an ultraviolet air sterilizer having a blowing fan and a UV lamp;
Measuring the temperature and humidity of the indoor space in which the air sterilizer is located;
Calculating a food poisoning index based on the measured temperature and humidity; And
Controlling the operating intensity of the blowing fan and the UV lamp according to the food poisoning index,
Wherein the step of controlling the operating intensity of the blowing fan and the UV lamp comprises:
When the air blowing speed of the blowing fan is increased, the intensity of the UV lamp is strongly controlled,
And controlling the intensity of the UV lamp to be weak when the air blowing speed of the blowing fan is low.

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