KR101489119B1 - wet type air cleaner - Google Patents

Abstract

The present invention relates to a wet air cleaner. According to the present invention, the cross-sectional area of an air path for the flow of contaminated air is locally reduced, a venturi is disposed for pressure reduction based on Bernoulli′s principle, and an inlet is arranged on a side surface of the venturi so that a cleaning solution is suctioned and flows into the venturi due to the flow of the contaminated air passing at a low pressure, the flow of the contaminated air and cleaning solution circulation are performed at the same time by a blowing device alone, and no pump is required for cleaning solution circulation. When the cleaning solution flows into the venturi, droplet spraying results from the high speed of the flow of the contaminated air, and thus the contaminants in the contaminated air can be effectively absorbed.

Description

Wet type air cleaner

More particularly, the present invention relates to a wet type air cleaner, and more particularly, to a ventilator for reducing the cross-sectional area of the air flowing through the ventilator by locally reducing the pressure by means of Bernoulli's principle, The cleaning liquid is sucked into the venturi by the flow of the polluted air passing through the ventilator so that not only the flow of contaminated air but also the circulation of the cleaning liquid can be performed at the same time by using only the ventilator, To a method for providing a wet type air cleaner that does not need to be provided.

BACKGROUND ART [0002] Techniques that serve as a background of the present invention are disclosed in Korean Patent Laid-Open Publication No. 10-2012-0028066 (March 22, 2012) and Japanese Laid-Open Patent Publication No. 2000-140547 (May 23, 2000).
Serious air pollution causes various diseases and threatens the health of modern people. The demand for air cleaners has increased rapidly, and a remarkable technological advance has been made especially for wet air cleaners that do not require filter replacement. The wet air cleaner is a device for blowing polluted air to make contact with the cleaning liquid by various methods and to adsorb and remove contaminants such as chemicals, plug powder, fine dust, bacteria,

Most air cleaners use forced convection rather than natural convection to induce a large flow of air. That is, a fan unit such as a fan or a blower is provided, and power is supplied so that the polluted air flows forcedly along a pre-designed path. The wet air cleaner must continuously spray a cleaning liquid for adsorbing contaminants into the flow of polluted air. If the cleaning liquid is scattered and discarded once, it is difficult to cover the cost, and a problem arises for treating the used cleaning liquid . Thus, a wet air cleaner will continue to circulate and reuse a limited volume of cleaning fluid. As a result, the wet air cleaner must have a separate power unit for circulating the washing liquid as well as a blower for causing the flow of polluted air. For this purpose, a rotary disk or a pump is widely used.

As described above, the circulation of the cleaning liquid in the wet type air cleaner is essential. To this end, a separate power unit separate from the air blowing unit is additionally provided. As a result, noise is increased, power is increased, The maintenance becomes difficult, and the price of the apparatus increases.

The present invention has been devised to solve the above problems, and it is an object of the present invention to provide a wet type air cleaner which can not only cause a flow of polluted air using only a blowing device but also circulate the cleaning liquid, And to provide the above-mentioned objects.

In order to accomplish the above object, the present invention provides a venturi to a path through which polluted air passes, thereby locally increasing the speed of the polluted air and lowering the pressure. In the venturi side, an inlet is provided, The low pressure causes the wash fluid in the reservoir to be sucked up. In addition, the cleaning liquid flowing into the venturi is ejected into the droplet by the rapid velocity of the polluted air passing through the venturi, thereby effectively removing contaminants.

The present invention has the effect of removing a separate device such as a pump or a rotating disk for circulating the cleaning liquid. The present invention has the effect of allowing the flow of contaminated air and the circulation of the cleaning liquid to be performed at the same time using only a blower installed in the wet air cleaner. As a result, the wet-type air cleaner according to the present invention dramatically reduces the number of parts to be used, thereby reducing the cost of production of the apparatus. By replacing dynamic parts with high probability of failure with static parts, Lowering effect.

1 is a cross-sectional view showing an embodiment of a wet type air cleaner according to the present invention
2 is a perspective view of a wet air cleaner according to an embodiment of the present invention,
Figure 3 shows a cross-sectional view of the venturi and orifice and a graph showing the change in pressure and velocity of the fluid flow through it
4 is a graph comparing the pressure loss of a venturi and an orifice
5 is a characteristic curve of a general fan system and system
FIG. 6 is a cross-sectional view showing the swirling flow of the polluted air generated in the venturi and the movement of the cleaning liquid in the embodiment of the present invention
7 is a cross-sectional view showing one embodiment of the wet type air cleaner of the present invention having a supply pipe and a liquid level holding device

In order to achieve the above object, one embodiment according to the present invention will be described in detail with reference to FIG. 1 and FIG.

In the wet air cleaner 1000 according to the present invention,

A case 100 in which a path 110 through which polluted air passes is formed;

An air blowing device 200 for causing a flow of gas so that polluted air passes along a path 110 formed in the case 100;

A cleaning liquid 300 flowing into a portion of the path 110 formed in the case 100 to absorb contaminants contained in the contaminated air and to move to the lower portion of the path 110 by gravity;

A storage tank 400 for collecting the washing liquid 300 flowing down to the lower portion of the path 110;

A venturi (500) for locally reducing the cross-sectional area of the path (110) through which polluted air passes to increase the speed of the polluted air flow and lower the pressure;

An inlet 600 installed at a side surface of the venturi 500 to introduce the cleaning liquid 300 into the path 110;

A supply pipe 700 connecting the cleaning liquid 300 so as to be able to move from the reservoir 400 to the inlet 600;

.

The wet air cleaner 1000 of the present invention is provided with a path 110 through which contaminated air containing contaminants flows in the case 100 as in a general air cleaner. It is desirable to reduce the air resistance and the pressure loss that cause energy loss so that the load for the air flow is minimized in designing the shape of the path 110. Therefore, In particular, by eliminating sudden expansion and sudden contraction which cause turbulent flow by causing turbulent flow, and eliminating obstacles or steps, it is possible to prevent the airflow from laminar flow Laminar flow should be maintained. The sectional area of the guide 110 is determined so that the air flow has a proper flow rate at each point of the guide 110. The cross sectional area is preferably smoothly changed continuously so as to reduce the occurrence of turbulence and minimize pressure loss, Thereby increasing the efficiency of the apparatus. FIG. 2 is a perspective view of a side view of a wet air cleaner 1000 according to an embodiment of the present invention. The cross sectional area of the cross-sectional area of the cross-sectional area of the cross-sectional area of the cross-sectional area of the cross-sectional area of the cross- Sectional area of the section where the air is discharged. The flow velocity of the airflow is slowed in a section where the cross-sectional area of the cross-section 110 is wide, and the flow velocity is increased in a section where the cross-sectional area is small. If the cross-sectional area of the cross-section 110 is too small, the drag increases drastically due to the rapid flow velocity, and the air resistance becomes worse. Therefore, proper design is required.

In implementing the present invention, the air blowing device 200 is provided at one point of the path 110 formed in the case 100 to circulate the polluted air. It is possible to install the ventilation device 200 at any point on the path 110. However, it is easy to manage the ventilation device 200 when it is attached to an end such as an entrance or an exit. When the ventilator 200 is installed at the inlet, the pressure of the ventilator 110 maintains a positive pressure slightly higher than the atmospheric pressure. When the ventilator 200 is installed at the exit, ) Maintains a negative pressure slightly lower than the atmospheric pressure. In the present invention, since the cleaning liquid 300 is sucked into the cleaning liquid 300 at a low pressure formed in the venturi 500, it is possible to maintain the airflow path 110 at a constant pressure, So that the contaminated air is sucked into the case 100. In the preferred embodiment of the present invention, in order to prevent corrosion or breakdown of the air blowing apparatus 200 due to the inflow of the washing liquid 300 and to prevent the washing liquid 300 scattered by the droplets 310 from flowing out, 200 may be provided with a filter membrane 210 at the front end thereof. In choosing the ventilator 200 for the present invention, a turbomachinery with a high efficiency is employed to produce a fan or radial flow that causes axial flow. A centrifugal fan, such as a blower, may be used, or any other type of ventilator 200 may be used. However, it is necessary that the air blowing device 200 can form a minimum pressure difference that can cause a flow rate of a normal air flow so that the wet air cleaner 1000 can be driven. However, if the capacity of the air blowing device 200 is excessively large Also, power consumption, vibration and noise can cause problems.

The wet air cleaner 1000 causes contaminated air to contact the cleaning liquid 300, thereby causing the pollutant to move from the contaminated air to the cleaning liquid 300. Therefore, the cleaning liquid 300 should be introduced into the path 110 and guided to the maximum possible contact with the contaminated air. The cleaning liquid 300 may be sprayed into droplets 310 into the flow of polluted air and the cleaning liquid 300 may flow along the side surface or the bottom surface of the path 110 to cause surface contact with the polluted air, The washing liquid 300 may be drawn down along the stepped path to form a multi-stage waterfall and the washing liquid 300 may be discharged as fractions, and the contact between the contaminated air and the washing liquid 300 may be maximized, So as to adsorb the contaminants.

In one embodiment of the present invention shown in FIG. 1, a part of the cleaning liquid 300 introduced into the venturi 500 is sprayed into the droplet 310, and a part of the cleaning liquid 300 flows down through the path. The chamber 120 has a wide cross-sectional area and is installed downstream of the venturi 500. The contaminated air flows into the droplets 310 of the sprayed cleaning liquid 300 while the contaminated air stays in the chamber 120 at a low speed, Thereby allowing the pollutant to be effectively absorbed while passing through the stagnant polluted air. The cleaning liquid 300 flows down along the path 110. The direction of the path 100 is alternately switched so that the cleaning liquid 300 falls down at the turning point of the path 100 so that the contaminated air and the cleaning liquid 300) was maximized.

Depending on which liquid is used as the cleaning liquid 300, the absorption rate of pollutants in the air cleaner can be changed. The use of water as the washing solution 300 makes it easy to obtain and inexpensively clean the path 110 and the storage tank 400 while suppressing the propagation of bacteria and preventing moss inside the washing solution 300. [ It is necessary to take measures such as adding a chemical substance, providing an ultraviolet sterilization device, or making the case of an antibacterial material. If the contaminant to be absorbed is a component that does not dissolve in water, use a non-aqueous solvent or an organic solvent.

Particularly, in the circulating method of the washing liquid 300 provided in the present invention, the flow rate of the washing liquid 300 is changed according to physical properties such as specific gravity and viscosity of the washing liquid 300, This will be discussed in detail later. As described above, the cleaning liquid 300 flowing into the path 110 absorbs contaminants through various paths and moves downward by gravity.

The washing liquid 300 flowing down to the lower portion of the path 110 is recovered in the storage tank 400. As shown in FIG. 1, when the liquid level of the storage tank 400 is further reduced by additionally supplying the supply tank 410, the amount of the cleaning liquid 300 may be reduced, The washing liquid 300 may flow out of the storage tank 410 to maintain the liquid level of the storage tank 400. Alternatively, as shown in FIG. 6, the replenishment pipe 420 may be connected so that the washing liquid 300 may be directly supplied from the external water pipe or oil pipe. When the liquid level of the storage tank 400 is lowered, And a liquid level maintenance device 430 for supplying the cleaning liquid 300. In the embodiment of FIG. 6, the buoy is raised or lowered according to the liquid level of the washing liquid 300, the valve is opened when the liquid level is lowered, and the liquid level is lowered The valve was closed and the liquid level was maintained. If the cleaning liquid 300 does not need to be replenished, the replacement period of the cleaning liquid 300 becomes longer, and convenience is improved. The method of replenishing the washing liquid 300 is not limited to the embodiment using the replenishing container 410 or the replenishing pipe 420 as shown in the drawings, but may be variously modified by referring to the embodiment.

The components described so far are used as they are in the present invention as a general component widely used in the conventional wet air cleaner 1000. [ The conventional wet air cleaner 1000 is a means for drawing up the cleaning liquid 300 flowing into the storage tank 400 and introducing the cleaning liquid 300 back into the furnace 110. The wet air cleaning apparatus 1000 includes a rotary motor 300 for circulating the cleaning liquid 300 using a pump, Or a wheel for circulating the washing liquid 300 is applied to the washing liquid 300. However, the additional power source is separately provided. The differentiated method of the present invention is a method in which the venturi 500 is inserted into the path 110 without using any additional power mechanism such as a pump or a motor, To suck it in.

Fluid dynamics is a component of a venturi, an orifice, or a nozzle that is used to localize the sectional area of a pipeline for a given flow rate to change the trade-off between pressure and velocity. nozzle) are used. When the flow rate of the fluid passes through the narrow cross-sectional area in the same state, the flow rate increases. As the kinetic energy increases due to the increase of the flow velocity of the fluid, the energy due to the pressure is lowered so that the total amount of energy is preserved. Figure 3 shows the cross-sectional shapes of the venturi and orifice and the changes in velocity and pressure in fluid flow through each location. As shown in the upper part of Fig. 3, the venturi changes continuously smoothly in cross-sectional area, but the orifice shrinks suddenly in cross-sectional area and then expands again after passing through a narrow section. The venturi and orifice shapes are different, but the flow of fluid through them is very similar. If the flow of the fluid meets the narrow cross-sectional area of diameter d beyond the broad cross-sectional area as the diameter D , such as the change in the flow velocity shown in the middle of FIG. 3, the velocity increases as the cross- The speed is restored to normal. As shown in the lower part of FIG. 3, when the velocity of the fluid flow increases, the pressure decreases, and when the velocity decreases to the original velocity, the pressure increases again. At this time, the difference between the venturi and the orifice appears. In the case of the venturi, the pressure is restored to its original state because there is almost no loss of energy. In the case of the orifice, the pressure is not restored as much as the energy loss. In this way, the cross sectional area is gradually changed to keep the laminar flow to the maximum, so that the occurrence of the pressure loss is small and most of the energy is saved. The venturi is called the venturi, and the pressure loss due to the turbulent flow is high, .

Fig. 4 shows the pressure loss and the restoration rate of the venturi and the orifice which are locally reduced from D to d in the flow of fluid passing through a pipe having a circular cross-section. The abscissa represents the ratio d / D , and the ordinate represents the percentage of the pressure loss and the restoration percentage. It can be seen that the pressure loss of the venturi is small while the pressure loss of the orifice is very large at the same diameter ratio. In the case of venturi, the pressure of 70% or more is restored regardless of the diameter ratio. However, in the case of the orifice, the pressure restoration rate is only 70% even if the sectional area is not large. When the diameter ratio d / D is small, , It can be seen that the pressure loss sharply increases and the recovery rate remarkably decreases.

In the present invention, the venturi (500) is referred to as a venturi and an orifice which are classified in the fluid mechanics, and the pressure and the velocity are switched by changing the sectional area of the conduit. In a wet air cleaner, it is substantially not easy to maintain laminar flow in the venturi 500 and to develop laminar flow with a sufficient transient region. As a result, the venturi 500 of the present invention tends to dominate the behavior of the orifice having a higher pressure loss than the behavior of the venturi with a low pressure loss.

The total air resistance and the pressure loss are determined according to the length and shape of the whole of the path 110 when the ventilator 500 and the path 110 are designed in the wet air cleaner 1000 of the present invention, So that the flow rate of the contaminated air is determined to be constant. Fig. 5 shows a characteristic curve of the general fan apparatus 200 and the system. The characteristics of the blower 200 are shown by solid lines, and the characteristics of the system are shown by dotted lines. The horizontal axis represents the flow rate and the vertical axis represents the pressure. The smaller the resistance on the path 110, the lower the required pressure and the smaller the load, the larger the flow rate that can be generated by the air blowing device 200 is. The maximum flow rate Q _max can be generated by operating the ventilator 200 in the air with no pressure to resist. The larger the resistance of the path 110, the smaller the flow rate, because the ventilator 200 must generate a higher pressure to overcome the pressure loss and produce the flow. The point at which the graph meets the longitudinal axis shows the maximum pressure P _max generated by the blower 200 when the maximum load is applied. This means the maximum pressure P _max that can be formed in a state in which there is no flow, such as air sucking by installing the ventilator 200 in a closed space.

In a general system using the blower 200, the resistance increases as the flow rate increases, and accordingly the pressure loss is also increased. When the fan apparatus 200 is started to operate, a flow of the fluid is generated in the system, so that the flow rate gradually increases. However, since the flow rate of the system is still small at the beginning of operation, Is much larger, the flow rate continues to increase. As shown by the arrow in FIG. 5, as the flow rate of the system increases over time and the pressure load increases, the operating point moves along the curve to the upper right corner. On the other hand, in the air blowing device 200, the pressure that can be generated in accordance with the increase in the flow rate gradually decreases, and the gap with the pressure load of the system gradually decreases, thereby slowing the increase of the flow rate. Eventually, over time, at the point where the two curves meet, the working point is stabilized in equilibrium, and the flow of the fluid is stable, keeping the pressure and flow constant.

In the present invention, when the shape of the path 110 is complicated and the resistance is large, the pressure loss is greatly increased and the flow rate is also reduced. Particularly, in the present invention, since the pressure loss occurring in the venturi (500) occupies a large portion of the pressure loss occurring in the entire path (110), the ventilation device 200) should be selected.

Hereinafter, the pressure at which the venturi 500 of the present invention is produced and the maximum height and flow rate at which the cleaning liquid 300 can reach are analyzed. In interpreting the behavior of gases such as polluted air, compressibility must be considered. However, since the flow rate of air cleaners is low and the pressure is not high, it is assumed that the polluted air is incompressible in all the analyzes. I want to. In order to improve the accuracy of the analyzed results, the calculated value should be corrected considering compressibility.

In the wet air cleaner 1000 according to the present invention, when the capacity of the air blowing device 200 is selected, the flow rate Q is determined according to the pressure loss of the designed air path 110. The flow rate Q of the contaminated air is the same at all points on the path 110 and the flow velocity of the contaminated air changes according to the cross sectional area of each point of the path 110. [ The average velocity v _i of the polluted air passing through a point i of the crossing 110 having the cross-sectional area A _i can be calculated as follows.

In Equation 1, the average velocity of the polluted air is inversely proportional to the cross-sectional area of the point. Therefore, the average velocity v _venturi of the polluted air passing through the narrow cross-sectional area A _venturi of the _venturi 500 is as follows.

In the present invention, the inlet pipe 600 is provided on the side of the venturi 500, and the supply pipe 700 connecting the storage vessel 400 to the inlet port 600 is installed so that the cleaning liquid 300 flows from the reservoir 400 into the inlet (600). When the pressure of the polluted air passing through the venturi 500 is lower than the pressure of the storage tank 400, the cleaning liquid 300 may flow into the path 110 through the supply pipe 700 connecting the both sides. Therefore, the present invention for circulating the cleaning liquid 300 without using a separate power device such as a pump can be used to analyze the pressure difference between the both ends of the supply pipe 700, that is, the inlet port 600 and the reservoir 400 very important. Assuming that the flow of polluted air is incompressible, Bernoulli's theorem widely used in fluid mechanics is to be used.

Bernoulli's theorem defined in equation (3) means that energy is constantly conserved at two points on the stream line and therefore does not reflect the energy loss due to the friction of the viscos flow. In the wet air cleaner 1000 of the present invention, as the two points of the polluted air flow, the first point is designated as the venturi 500 and the second point as the reservoir 400, as shown in Fig. 1, 3 is applied as follows.

는 동일한 것으로 가정하였다. 공기의 밀도는 물과 비교할 때 약 1/1000의 값을 갖으며, 대기압에서 약 1.293 kg/m³이 된다. 수학식4를 정리하여, 벤추리(500)와 저장조(400)에 연결된 공급관(700)의 양단에서의 압력차 p_diff 를 다음과 같이 산출 할 수 있다.
The pressure and flow rate of the polluted air passing through the venturi 500 are _expressed as P _venturi and v _venturi , respectively, and the pressure and flow rate of the polluted air passing through the storage tank 400 are denoted by P _reservoir and v _reservoir , respectively. Respectively. As shown in Fig. 1, the height of the liquid level of the _reservoir is denoted by h _reservoir and the height of the _venturi is denoted by h _venturi , and the difference is equal to the height h _{pipe of the} supply _pipe . Ignoring the compressibility of polluted air,

Are assumed to be the same. The density of air is about 1/1000 of that of water and about 1.293 kg / m ³ at atmospheric pressure. The pressure difference p _diff at both ends of the supply pipe 700 connected to the venturi 500 and the storage tank 400 can be calculated as follows.

가 매우 작을 뿐 아니라, 공기청정기의 경우 공급관(700)의 높이 h _pipe 가 최대 수 미터 이내 이므로, 우항에 포함된 위치압력

을 무시하면 다음과 같이 단순화 할 수 있다.
Density of polluted air

Since the height h _pipe of the supply pipe 700 is within a maximum of several meters in the case of the air purifier,

Can be simplified as follows.

Suppose that the turbulence generation of the venturi 500 of the present invention is small and the pressure loss is small and most of the pressure after the venturi 500 is restored and the venturi 500 calculates the pressure P _diff to suck the cleaning liquid 300 Respectively. The venturi 500 in the present invention is designed in a similar ohripiseugwa-like vortex is generated and in the case that due to the warm pressure difference of the center and the wall surface largely formed, the venturi 500 is sucking the cleaning fluid 300 to the pressure difference P _diff can be interpreted in other ways as follows.

6, when the shape of the venturi 500 of the present invention is designed so that the cross-sectional area is repeatedly reduced and expanded rapidly, a cavity is formed in the subsequent wall surface of the rapid expansion portion, and a vortex flow ). In carrying out the present invention, it is intended to analyze the case where the inlet 600 is installed in a portion where the pressure is low by the vortex to suck the cleaning liquid 300. As shown in FIG. 6, when the Bernoulli theorem is applied, the center portion through which the contaminated air passes at a high flow rate is selected as the first point, the inlet 600 formed with the vortex is selected as the second point, The pressure P _diff to be drawn into the chamber 500 can be calculated as follows.

을 무시하였으며, 공기의 밀도가 양 지점에서 동일하다고 가정하였다. 실제적으로 와류에 의한 공기의 밀도의 변화 및 압축성의 영향이 상당하여 단순히 베르누이 정리를 적용할 것이 아니라 압축성을 고려한 실험식을 사용하는 것이 바람직하다. 수학식 7에서 벤추리(500) 중심과 벽면에서의 압력을 각각 p _venturi 와 p _wall 로 표시하고, 양지점에서의 속력을 각각 v _venturi 와 v _wall 로 표시하였다. 와류가 발생하는 벤추리(500) 벽면의 유속을 0으로 처리하면, 벤추리(500)의 중심을 통과하는 빠른 속도의 공기가 유입구(600)를 통해 세척액(300)을 빨아들이는 압력 P _diff 를 다음과 같이 단순하게 계산할 수 있다.
When the Bernoulli's theorem is applied in Equation (7), since the height difference between the central portion of the path 100 and the bottom wall surface at which the inlet port 600 is located is very small,

And the air density was assumed to be the same at both points. In practice, the influence of the change in air density due to the vortex and the effect of compressibility is significant, so it is not merely to apply Bernoulli's theorem, Is preferably used. In Equation (7), the pressures at the center and wall of the venturi (500) are denoted by p _venturi and p _wall , respectively, and the velocities at the supine point are denoted by v _venturi and v _wall , respectively. If the velocity of the wall surface of the venturi 500 in which the vortex is generated is set to 0, a high velocity air passing through the center of the venturi 500 is sucked through the inlet 600 by the pressure P _diff As shown in FIG.

Two methods for calculating the pressure P _diff at which the cleaning liquid 300 is drawn up to the supply pipe 700 are exemplified and the results are summarized in equations (6) and (8). In the behavior of the polluted air according to the shape of the designed venturi 500, if the laminar flow characteristics are large, it becomes similar to the calculated value of the equation (6) of the former. If the behavior of the turbulent flow becomes dominant, It becomes. To determine whether the effects of laminar flow and turbulence are dominant, the Reinold's Number can be calculated and used, and an empirical formula using various correction coefficients can be utilized. Since the compressibility is not considered in the above-described analysis method, the error is significant. The present invention concentrates on explaining the principle rather than an exact numerical interpretation.

The maximum height h _{liquid , max} and flow velocity v _liquid of the venturi 500 that the venturi 500 can reach by the pressure P _diff sucking the cleaning fluid 300 is calculated. Until now, the Bernoulli's equation has been applied to the polluted air flow, but this time the Bernoulli theorem applies to the flow of the wash fluid 300.

는 세척액(300)의 밀도, g는 중력가속도이며, 따라서 비중량

을 사용하여 축약하여 표현할 수 있다. p _diff 는 벤추리(500)가 생성하는 압력으로서 수학식 6과 수학식8에서 해석한 바 있다. 수학식 9는, 펌프의 용량을 표현하는데 널리 사용하는 압력수두(water head)와 같이, 벤추리(500)가 생성하는압력 p _diff 을 세척액(300)의 밀도

에 대한 수두 h _{liquid , max} 로 표현한 것이다. 수학식 9의 해석결과는, 본 발명에 있어서, 세척액(300)이 빨아 올려질 때에, 수두 h _liquid,max 이상 도달할 수 없음을 의미하며, 반대로 공급관(700)을 이보다 낮게 하면 세척액(300)의 흐름이 가능하다는 것을 보여준다. 따라서, 본 발명의 송풍장치(200)의 용량을 선정하거나, 벤추리(500)의 형상을 설계함에 있어서, 수학식 9에 의해 계산된 벤추리(500)의 수두 h _{liquid , max} 가 설계된 공급관(700)의 높이 h _pipe 를 충분히 넘어서도록 하여야 한다.In Equation (9)

Is the density of the cleaning liquid 300, g is the gravitational acceleration,

Can be expressed in abbreviated form. p _diff is the pressure generated by the venturi (500) and is interpreted in Equations (6) and (8). Equation 9 shows the pressure p _diff produced by the venturi 500, such as the pressure head widely used to express the capacity of the pump,

The head is expressed as h _{liquid , max} . The analysis result of Equation 9 means that when the washing liquid 300 is sucked up _, it can not reach the head h _{liquid, max} . On the contrary, if the supply line 700 is lowered, Of the flow is possible. Therefore, when selecting the capacity of the ventilation device 200 of the present invention or designing the shape of the venturi 500, the supply tube 700 designed for the head h _{liquid , max} of the venturi 500 calculated by the equation (9) The height h of the _pipe .

로 전환되기 때문에, 아래와 같이 표현할 수 있다.
Let the height of the inlet 600 be lower than the head h _{liquid , max} of the venturi 500 calculated in Equation (9), and analyze the velocity and the flow when the flow of the washing liquid 300 occurs. Head h _liquid, part of the _max of the venturi 500 includes a cleaning solution 300 is used I the dates back height h _pipe of a supply pipe 700, and the rest of the head h _{liquid, max} - h _pipe a flow of cleaning solution 300 , And eventually,

, It can be expressed as follows.

In Equation (10), the ejection speed v _liquid of the washing liquid 300 is obtained as follows.

Equation 8 is substituted into Equation 11 to express the ejection speed v _liquid of the cleaning liquid 300 as a function of the velocity v _venturi of the polluted air passing through the venturi 500 and the height h _pipe of the supply pipe 700 as follows .

When the circulation amount of the cleaning liquid 300 is increased in the practice of the present invention, the height h _pipe of the supply pipe 700 may be lowered, the liquid having a low specific gravity may be used as the cleaning liquid 300, It is necessary to increase the velocity v _venturi of the polluted air passing through the filter 500. Since the specific gravity of water is generally lower than that of oil, a circulation amount can be increased by using water or using a liquid having a specific gravity lower than that of water as the washing liquid (300). Another way to increase the circulation amount of the cleaning liquid 300 is to increase the velocity v _venturi of the polluted air passing through the venturi 500. A method that to increase the velocity v _venturi of the contaminated air, increasing the flow rate itself, or by changing the shape of a venturi (500) within a defined flow rate to speed up by reducing the cross-sectional area. In order to increase the flow rate of polluted air as a whole, it is necessary to install a larger capacity blower 200, which requires more power. The flow rate can be increased by reducing the cross-sectional area of the venturi 500 in a state where the blowing device 200 is determined and the flow rate is determined. However, if the cross-sectional area is excessively reduced, the effect of turbulence due to sudden expansion and sudden contraction increases, and the energy loss of the blower 200 decreases due to an increase in pressure loss. Therefore, the most preferable method is to optimize the shape of the cylinder 110 including the venturi 500 so as to minimize the loss of energy, and to remove the contaminated air at a proper flow rate in the shape of the predetermined venturi 500 and the cylinder 110 It is preferable to select the capacity of the air blowing device 200 capable of making the flow of the airflow.

The equation (12) defines the ejection speed v _liquid of the washing liquid 300. Theoretically, if the cross-sectional area of the feeding tube 700 is wider, the flow rate of the washing liquid 300 increases in proportion thereto. Can be used to increase the circulation amount. Above all, since the circulation amount of the cleaning liquid 300 is high, the water absorption rate of the wet air cleaner 1000 is not increased, so it is necessary to maintain the circulation amount of the cleaning liquid 300 at an appropriate level. In carrying out the present invention, the circulation amount of the cleaning liquid 300 may be adjusted by providing the valve 710 in the supply pipe 700 with a sufficient circulation amount of the cleaning liquid 300 secured.

If the influence of the height h _pipe of the supply pipe 700 included in the equation (12) is removed by assuming a special case in which the position of the venturi 500 is approximately at the same height as the liquid level of the storage tank 400 in Equation (12) A simple mathematical expression can be obtained as follows.

수학식 14는, 수학식 2에 수학식 9를 대입한 것으로서, 오염공기의 유량 Q 및 벤추리(500)의 협소한 단면적 A_venturi 과, 본 발명에 따른 세척액(300)의 흐름을 유발할 수 있는 공급관(700)의 높이 h_liquid,max 의 관계를 알 수 있다.
Equation 13 shows that the ejection speed v _liquid of the washer fluid 300 is proportional to the velocity v _venturi of the polluted air passing through the venturi 500 and its proportional coefficient becomes the square root of the ratio of the air and the density of the washer fluid 300 it means. When the water is used as the washing liquid 300, the jetting speed v _liquid of the washing liquid 300 is lower than the air-to-air ratio of the polluted air passing through the venturi 500 Of the velocity of the _venturi . This is based on a special assumption, but the relationship between the ejection velocity v _liquid of the washer fluid 300 and the velocity v _venturi of the polluted air can be roughly estimated. The ejection speed v _liquid of the actual washing liquid 300 is much smaller than this.

Equation (14) is obtained by substituting Equation (9) into Equation (2), which is the sum of the flow rate Q of contaminated air and the narrow cross-sectional area A _venturi of the venturi 500 and the flow rate of the cleaning liquid 300 according to the present invention The relation of the height h _{liquid, max} of the light source 700 can be known.

The venturi 500 according to the present invention may function not only to infiltrate the cleaning liquid 300 but also to spray the inflowing cleaning liquid 300 into the droplet as the shape of the venturi 500 is adjusted. When the cleaning liquid 300 flows into the venturi 500, it is blown into the polluted air and scattered in droplets to be sprayed. When the cleaning liquid 300 is sprayed into the droplet, the contact area with the contaminated air increases, thereby increasing the chance of absorbing the contaminant. The flow rate of the contaminated air is controlled by changing the cross-sectional area of the cross-flow path, so that the flow rate of the droplet 310 of the cleaning liquid 300 and the contaminated air It is possible to increase the chance that the pollutant comes into contact with the cleaning liquid 300. [

In the present invention, the shape of the venturi 500 is adjusted so that the cleaning liquid 300 can be sprayed into the droplet, and the sectional area of the path 110 following the venturi 500 is widened as shown in Fig. 1, The provision of the chamber 120 in which the flow rate of the air can be lowered allows the droplets 310 of the sprayed cleaning liquid 300 to fly while maintaining the momentum, As the air penetrates and the opportunity to hit the pollutant increases, the absorption rate of the pollutant can be maximized.

A case 100; A path 110;
A chamber 120; A blower 200;
Shielding film 210; Cleaning liquid 300;
A droplet 310 of wash fluid; A reservoir 400;
A supply container 410; A replenishment pipe 420;
A liquid level holding device 430, a venturi 500;
An inlet 600; A supply pipe 700;
A valve 710; A wet air cleaner 1000;

Claims (8)

A case 100 in which a path 110 through which polluted air passes is formed;
A blowing device (200) for causing a flow of gas through the path (110) so that polluted air passes through the path;
A cleaning liquid 300 that flows into a section of the path 110 and absorbs contaminants contained in polluted air and moves to a lower portion of the path 110 by gravity;
A storage tank 400 for collecting the washing liquid 300 flowing down to the lower end of the path 110;
A venturi 500 that locally reduces the cross-sectional area of the path 110 to increase the velocity of polluted air and lower the pressure;
An inlet 600 installed at a side surface of the venturi 500 to introduce the washing liquid 300 into the furnace 110;
A supply pipe 700 connecting the cleaning liquid 300 so as to be able to move from the reservoir 400 to the inlet 600;
, Where g is the gravitational acceleration,

Is the density of the polluted air,

Is the density of the wash liquid 300,

Is the average velocity of the polluted air passing through the narrow section of the venturi (500), the height h _pipe of the supply pipe (700)

Lt; RTI ID = 0.0 > 1000, < / RTI >
The method according to claim 1,
The wet air cleaner 1000 in which the cleaning liquid 300 is scattered and ejected as droplets when the cleaning liquid 300 flows into the path 110 through the inlet 600,
The method of claim 2,
A wet air cleaner 1000 having a chamber 120 having a cross-sectional area widened so that the contaminated air stagnates at a slow rate is provided at one point of the path 100 following the venturi 500,
The method according to claim 1,
A wet air cleaner 1000 having a valve 710 installed at one point of the supply pipe 700 so as to control the flow rate of the cleaning liquid 300 flowing into the inlet 600,
The method according to claim 1,
A wet air cleaner 1000 having a replenishing container 410 or a replenishing pipe 420 for replenishing the cleaning liquid 300 of the storage tank 400,
The method of claim 5,
A wet air cleaner 1000 having a liquid level maintenance device 430 for constantly adjusting the liquid level of the cleaning liquid 300 of the storage tank 400,

The method according to claim 1,
g is the gravitational acceleration,

Is the density of the polluted air,

Is the density of the cleaning liquid 300, h _pipe is the height of the supply _pipe 700, and Q is the flow rate of the polluted air generated by the air blowing device 200, the width of the narrow cross-sectional area A _venturi of the venturi 500 Is expressed by the following equation

Lt; RTI ID = 0.0 > 1000, < / RTI >
The method according to claim 1,
g is the gravitational acceleration,

Is the density of the polluted air,

The flow rate Q of the polluted air generated by the air blowing apparatus 200 is represented by the following equation (1), where h _pipe is the height of the supply _pipe 700 and A _venturi is the narrow cross- ≪

Lt; RTI ID = 0.0 > 1000, < / RTI >

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