KR101045986B1 - Heat treatment device for indoor airborne microbial sterilization - Google Patents

Abstract

Heat treatment apparatus for indoor airborne microbial sterilization of the present invention is a casing having an air inlet and an air outlet, a fan installed at the air inlet of the casing, a heat treatment unit installed upright inside the casing and sterilizing air by a hot wire unit; It is installed at the air inlet of the casing includes an air hopper for concentrating air. According to the present invention configured as described above, by using a heating wire provided in the heat treatment device to sterilize it can prevent the generation of ozone by the use of ultraviolet rays, and unlike the electrostatic precipitator can also sterilize microorganisms can increase the sterilization effect There is an advantage to that.

Airborne Microorganism, Heat Treatment Part, Heater Part, Controller

Description

Heat treatment device for indoor airborne microbial sterilization {HEAT TREATMENT DEVICE FOR STERILIZING INDOOR FLOATING MICROORGANISM}

The present invention relates to a heat treatment apparatus for sterilizing indoor airborne microorganisms, and more particularly, to a heat treatment apparatus for sterilizing microorganisms suspended in a room using a heating wire.

Recently, the utilization of indoor or underground space is increasing due to the increase of traffic volume and the increase of the floating population. In such indoor or underground spaces, since the flow population is large and artificially circulates the internal air, the quality of air is inevitably deteriorated.

Therefore, the air supplied to the indoor or underground space should be discharged to the outside and the air circulated continuously by introducing the outside air into the inside. However, the problem of stimulating the asthma of humans or the mucous membrane of the eye occurs in the process of circulating the air, the problem is solved by using a clean air system to remove the microorganisms.

In such a clean air system, an apparatus for sterilizing microorganisms suspended in the air plays an important role. Conventional sterilizers include an ultraviolet sterilizer for sterilizing microorganisms using ultraviolet rays and an electric dust collector for collecting and removing fine dust. .

However, in the case of ultraviolet sterilizers, there is a problem that harms the health of people who work in the internal space by generating ozone harmful to the human body. In addition, in the case of the electrostatic precipitator, only the dust in the air is removed, there is a problem in that it cannot sterilize floating microorganisms.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide an apparatus capable of sterilizing microorganisms without releasing harmful substances to the human body.

According to a feature of the present invention for achieving the above object, the heat treatment apparatus for indoor airborne microbial sterilization of the present invention comprises a casing formed air inlet and air outlet; And a fan installed at an air inlet of the casing; and a heat treatment unit installed inside the casing and sterilizing air introduced from the air inlet by a hot wire.

The casing of the present invention preferably includes a speed controller installed in the casing and adjusting the rotational speed of the fan, and a controller installed in the casing and controlling the speed controller by a pre-input signal.

The casing of the present invention preferably includes an anemometer, which is installed in the casing and measures the wind speed of air introduced into the casing.

The casing of the present invention preferably includes a wind pressure measuring device which is installed in the casing and measures the wind pressure formed by the air introduced into the casing.

The heat treatment part of the present invention is a hot wire plate installed upright in the casing; It is preferable to include a hot wire portion which is installed spaced apart at a predetermined interval on the hot wire plate; and a wind pressure control portion formed to be opened in the hot wire plate.

The heat treatment portion of the present invention is formed of a single hot wire plate, the cross section length of the hot wire plate is formed of a first type heat treatment portion is formed relatively short compared to the cross-sectional length of the casing, and two or more hot wire plate, The plates are preferably formed of a second type heat treatment part spaced apart at regular intervals.

Casing of the present invention preferably comprises an air hopper for concentrating air to the heat treatment.

According to the heat treatment apparatus for indoor airborne microbial sterilization according to the present invention, by using the heat wire part provided in the heat treatment apparatus to sterilize, ozone generation can be prevented by the use of ultraviolet rays, and unlike the electrostatic precipitator, microorganisms can be sterilized. Therefore, there is an advantage that can increase the sterilization effect.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the heat treatment apparatus for indoor airborne microbial sterilization according to the present invention will be described in detail.

1 to 4 illustrate a preferred embodiment of the heat treatment apparatus for sterilizing indoor airborne microorganisms according to the present invention. Heat treatment apparatus of the present invention can be installed connected to the indoor air inlet passage or air conditioning system apparatus.

As shown, the air inlet 11 and the air outlet 13 through which indoor air is drawn in and discharged are formed in the front and rear of the substantially rectangular casing 10. Air introduced through the air inlet 11 passes through the casing 10 and is discharged to the air outlet 13.

The air inlet 11 is provided with a fan 15 for introducing indoor air into the device of the present invention. The fan 15 is provided with a speed controller (not shown) for adjusting the rotational speed of the fan. The speed controller may adjust the amount of air introduced into the apparatus by adjusting the rotational speed of the fan 15.

Inside the casing 10, a mounting space for mounting various components is formed. An air hopper 17 is installed on one surface of the casing 10 in which the air inlet 11 is formed. The air hopper 17 is formed such that the opening becomes narrower from the direction of the air inlet 11 toward the interior direction. Therefore, the air drawn into the casing 10 by the air hopper 17 may be concentrated and drawn into the center portion of the inside of the casing 10.

In the internal mounting space of the casing 10, a plurality of heat treatment units 20 are installed upright. The heat treatment unit 20 serves to sterilize by heat-treating the microorganisms floating in the air introduced into the casing (10).

The heat treatment part 20 includes a hot wire plate 21 installed upright in the casing 10. The hot air plate 21 may be formed with a wind pressure control unit 23 opening to a predetermined size. The wind pressure control unit 23 may adjust the wind pressure applied to the hot wire plate 21 by passing a portion of the air introduced into the casing 10 through the opened hole.

In addition, the hot wire plate 21 is provided with a hot wire portion 25 which is spaced apart at a predetermined interval. The hot wire unit 25 serves to sterilize the microorganisms floating in the air introduced into the hot wire plate 21 by dissipating heat by the power supplied from the outside.

The heat treatment part 20 may be divided into a first type heat treatment part 20a and a second type heat treatment part 20b as illustrated in FIGS. 3 and 4. As shown in FIG. 3, the first type heat treatment part 20a includes a single hot wire plate 21, and the cross-sectional length of the hot wire plate 21 is shorter than the cross-sectional length of the casing 10. Is formed so that the air can pass through between the one end of the hot wire plate 21 and the inner surface of the casing (10).

In addition, the second type heat treatment part 20b may include two or more hot wire plates 21 as shown in FIG. 4. The side end of the second type heat treatment part 20b is installed to contact the side surface of the casing 10, and is separated from two or more heat wires by being spaced apart at a predetermined interval from the adjacent second type heat treatment part 20b. It is configured to allow air to pass between the plates 21.

Therefore, the heat treatment part 20 is composed of the first type heat treatment part 20a and the second type heat treatment part 20b so that the air drawn into the casing 10 is in contact with the hot wire plate 21 as much as possible. It can maximize the sterilization effect. In the present invention, the second type heat treatment unit 20 is formed to be separated from left and right, or may be formed to be separated up and down, or may be formed to be separated up and down and left and right.

In addition, a separate controller (not shown) may be provided inside the casing 10. In addition, the casing 10 may be provided with a wind pressure measuring unit (not shown) or a wind speed measuring unit (not shown).

The controller may adjust the speed controller of the fan 15 such that the wind pressure or wind speed measured by the wind pressure measuring unit or the wind speed measuring unit maintains a previously input wind pressure or wind speed value.

Hereinafter, the operation of the heat treatment apparatus for indoor airborne microbial sterilization according to the present invention having the configuration as described above will be described in detail.

When the fan 15 installed in the casing 10 is operated, air is introduced into the casing 10 through the air inlet 11 of the casing 10. The air drawn into the casing 10 is concentrated in the center by the air hopper 17 and flows into the first heat treatment part 20a.

The microorganisms suspended in the air introduced into the first heat treatment unit 20a are sterilized by the heating wire provided in the heat treatment unit 20a. In addition, the wind pressure adjusting unit 23 formed in the heat treatment unit 20a may adjust the wind pressure applied to the hot wire plate 21 by passing a part of air.

The air introduced into the first heat treatment part 20a passes through both side ends of the hot wire plate 21 and flows into the second heat treatment part 20b. The air introduced into the second heat treatment part 20b is also sterilized by the hot wire part 25 of the hot wire plate 21.

The air passing through the second heat treatment part 20b is sterilized while repeatedly passing through the first heat treatment part 20a and the second type heat treatment part 20b.

At this time, the controller provided in the casing 10 controls the rotational speed of the fan by adjusting the speed controller so that the wind pressure or wind speed measured by the wind pressure measuring unit or the wind speed measuring unit does not exceed a predetermined numerical range.

Experimental results using the heat treatment apparatus for indoor airborne microbial sterilization as shown above are shown in FIG. 5. 5 is a graph showing the suspended bacteria reduction efficiency at different temperature and wind speed conditions. 5 is a result calculated through Equation 1 below.

Reduction Ratio = (1- (CFU _out ) / (CFU _in )) * 100 (%)

In the above formula, CFU (Colony Forming Unit means the number of cells per basic unit, CFU _out means the CFU value after passing through the heat treatment apparatus and CFU _in means the CFU value before passing through the heat treatment apparatus.

First, looking at the rate of change according to temperature, it can be seen that the reduction efficiency of the floating bacteria at 150 ° C rather than 100 ° C. That is, when the flow rate is the same, it can be seen that the higher the temperature, the higher the rate of reduction of the airborne bacteria.

And, when the temperature is the same, it can be seen that the reduction efficiency is higher when the flow rate is slow. That is, in the above experimental conditions, the higher the temperature or the slower the flow rate (the longer the exposure time), the higher the reduction efficiency of the airborne bacteria.

On the other hand, in the case of the experimental value deviation, the deviation appears up to 40% at the high flow rate, but at the low flow rate, the deviation appears to be 20% or less, and it can be seen that the smaller the flow rate, the less the deviation of the experimental value. This can be presumed to be caused by the variation of the exposure level of the floating bacteria due to the increase in the turbulence caused by the heating wire inside the experimental apparatus at the high flow rate.

Within the scope of the basic technical spirit of the present invention, many other modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the claims to be described later. will be.

According to the heat treatment apparatus for indoor airborne microbial sterilization according to the present invention as described in detail above, the following effects can be obtained.

By sterilizing using a heat wire provided in the heat treatment apparatus, ozone generation can be prevented by the use of ultraviolet rays, and unlike electrostatic precipitators, microorganisms can be sterilized to increase sterilization effects.

1 is a perspective view showing a preferred embodiment of the heat treatment apparatus for indoor airborne microbial sterilization of the present invention.

Figure 2 is a cross-sectional view showing a heat treatment apparatus for indoor airborne microbial sterilization of the present invention.

Figure 3 is a perspective view showing a first heat treatment part of the heat treatment apparatus for indoor airborne microbial sterilization of the present invention.

Figure 4 is a perspective view showing a second heat treatment unit of the indoor airborne microbial sterilization heat treatment apparatus of the present invention.

Figure 5 is a graph showing the experimental results by the heat treatment apparatus for indoor airborne microbial sterilization of the present invention.

Explanation of symbols on the main parts of the drawings

10 casing 11: air inlet

13: air outlet 15: fan

17: air hopper 20: heat treatment

21: hot wire plate 23: wind pressure control unit

25: hot wire part

Claims (7)

A casing having an air inlet and an air outlet; A fan installed at an air inlet of the casing; and Is installed inside the casing, and includes a heat treatment for sterilizing the air flowing from the air inlet by a hot wire, The heat treatment unit A hot wire plate installed upright in the casing; A heating wire unit installed at a predetermined interval apart from the heating wire plate; and It includes a wind pressure control portion formed to be opened in the hot wire plate Heat treatment device for indoor airborne microbial sterilization. The method of claim 1, The casing is A speed controller installed in the casing and controlling a rotation speed of the fan; A controller installed in the casing and controlling the speed controller by a pre-input signal; Heat treatment device for indoor airborne microbial sterilization. The method of claim 2, The casing is Installed in the casing, including a wind speed measuring instrument for measuring the wind speed of air introduced into the casing Heat treatment device for indoor airborne microbial sterilization. The method of claim 2, The casing is Installed in the casing, including a wind pressure measuring instrument for measuring the wind pressure formed by the air introduced into the casing Heat treatment device for indoor airborne microbial sterilization. delete The method of claim 1, The heat treatment unit A first heat treatment part formed of a single hot wire plate and having a cross-sectional length of the hot wire plate relatively shorter than a cross-sectional length of the casing; It is formed of two or more hot wire plates, the hot wire plates are formed of a second type heat treatment portion spaced apart at a predetermined interval Heat treatment device for indoor airborne microbial sterilization. The method of claim 1, The casing is An air hopper for concentrating air to the heat treatment unit Heat treatment device for indoor airborne microbial sterilization.

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