KR100536574B1 - Absorption scrubber using multi vortex - Google Patents

Abstract

The present invention is an absorption cleaning apparatus using a multi swirl flow that uniformly mixes the liquid and / or gas to be supplied, the hollow casing 210, the one end of the casing extending inwardly in the interior and the liquid inside the casing Or a pipe 220 for inducing gas, a hollow bulkhead 250 having a height corresponding to the pipe, and having a smaller size than a casing, and a plurality of liquids or gases installed and supplied between the pipe and the partition wall in a streamlined manner. A plurality of first guide vanes (230) to pivot with a plurality of guide ribs and a plurality of installed and supplied between the partition and the casing to form a swirl flow of the same or slower speed than the swirl flow formed by the first guide vanes A plurality of second guide vanes 260 for turning the liquid or gas in a streamline shape, and a spray nozzle 240 installed at the end of the pipe to inject liquid or gas into the casing. The. The present invention has the effect of uniformly mixing gas and / or liquid more efficiently or warming and abandoning the liquid by using multi-swirl flows rotating at the same or different speeds along the central and inner surface portions of the casing.

Description

Absorption scrubber using multi vortex

The present invention relates to an absorption cleaning apparatus using swirling flows applicable to food, chemical, petroleum refining, environment, energy, papermaking, and other fields. In particular, the present invention relates to a gas and / or liquid uniformly using multiple swirling flows. The present invention relates to an absorption cleaning apparatus using multi swirl flows for mixing or heating and abandoning a liquid.

As a device for cleaning a gas containing contaminants, there are a centrifugal force cleaning device and a filling cleaning device.

Centrifugal force type cleaning device removes contaminants by spraying and absorbing water by spraying water from a plurality of manifolds when a gas containing contaminants is supplied through a gas supply unit formed with a damper to form a swirl flow. It is a device to discharge clean gas. However, the centrifugal force cleaning device has a disadvantage in that the structure is simple but the distance between the gas and the liquid can be in contact, that is, the distance of the gas is short and the equipment is excessively large or the pressure loss is greatly increased when installed in multiple stages.

In addition, when a gas containing contaminants is supplied through the gas supply unit, the rechargeable cleaning device filters the contaminants and the like through the filling layer and sprays water to clean and absorb the contaminants. It is a device that removes moisture through mist eliminator and discharges clean gas. However, the charging scrubber is limited in the amount of liquid spraying on the gas, that is, the gas-liquid ratio adjustment range, and in the case of the phenomenon of drift (gas flowing out of one side) or overflow (when the gas flow rate increases in the rechargeable scrubber) The injection liquid does not flow in the downward direction, but overflows to the upper side), thereby reducing the efficiency.

As described above, the conventional cleaning device is separated from each other, the gas supply unit for supplying the gas and the water injection unit for injecting water, and the structure of the gas supply unit is not suitable for gas supply, so that efficient cleaning is not possible.

In order to solve this problem, a technology related to "injection apparatus using a swirl flow, and a mixing apparatus and absorption cleaning apparatus using the same" developed and registered by the present inventor is described in Patent No. 237737. Looking at the injection device using the swirl flow of this technical content is as follows.

1 is a cross-sectional view showing the configuration of the injection device using a swirl flow of the prior art, Figure 2 is a plan view showing a coupling relationship of the guide blade of the injection device shown in FIG. As shown in FIGS. 1 and 2, the conventional injector 100 is a cylindrical casing 110 and an "a" shaped pipe 120 disposed above the upper center of the casing 110 to induce liquid or gas. ), And the blade is configured in the form of a blade to flow the liquid or gas supplied in a streamline form, one side is coupled to the pipe 120 and the other side is composed of a guide blade 130 is coupled to the inner side of the casing 110 do.

Looking at the operation relationship of the injection device 100 is configured as follows. First, when gas is supplied along the guide feather 130 positioned on the upper portion of the casing 110, the supplied gas forms a swirl flow while moving downward by the guide feather 130. When gas flows while forming a swirl flow along the inside of the casing 110, a liquid or gas is supplied through the pipe 120. In this way, the liquid or gas supplied through the pipe 120 is injected through the injection nozzle 140 installed at the end of the pipe 120 to make contact with the gas supplied while forming the swirl flow. As a result, when the gas and the gas are respectively supplied and contacted, the gas and the gas are uniformly mixed. When the gas and the liquid are supplied and contacted, the liquid absorbs and cleans the pollutants contained in the gas.

However, the injector 100 forms a swirl flow while the supplied gas moves downward by the guide vanes 130, but the rotation speed of the swirl flow is fast along the inner surface of the casing 110. The center of the casing 110 is relatively slow compared to the inner surface. Therefore, the liquid or gas injected through the injection nozzle 140 disposed on the center of the casing 110 is initially affected by the slow speed swirl flow formed in the center of the casing 110 and reaches a certain point in time. It is influenced by the high speed swirl flow formed on the inner side of the (110). As a result, there is a disadvantage that a more efficient homogeneous mixing of the gas and / or liquid is formed slow or difficult. On the other hand, when the size of the casing 110 increases, there is a disadvantage that this disadvantage occurs more.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by using a multi-swirl flow more efficiently and uniformly mixed gas and / or liquid using a multi-swirl flow to warm and give up the liquid The purpose is to provide an absorption cleaning apparatus.

The present invention for achieving the above object is an absorption cleaning apparatus using a multi-swirl flow for uniformly mixing the liquid and / or gas supplied, the hollow casing, and extending inward from the center of one end of the casing A pipe for inducing liquid or gas into the casing, a hollow partition wall having a height corresponding to the pipe and smaller in size than the casing, and a plurality of liquids installed and supplied between the pipe and the partition wall or A plurality of first guide vanes for swirling the gas in a streamline shape, and a plurality of first guide vanes between the partitions and the casing to form a swirl flow at a speed equal to or slower than that of the swirl flow formed by the first guide vanes. A plurality of second guide vanes that pivot the installed liquid or gas into a streamline form, and are installed at the end of the pipe It characterized in that it comprises a spray nozzle for injecting a liquid or gas into the casing.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the absorption cleaning apparatus using a multi-swirl flow in accordance with the present invention will be described in detail.

Figure 3 is a cross-sectional view showing the configuration of the absorption cleaning device using a multi-swirl flow in accordance with a first embodiment of the present invention, Figures 4 and 5 is a coupling relationship of the guide blade of the absorption cleaning device shown in FIG. It is a top view and an exploded perspective view shown.

As shown in Figures 3 to 5, the absorption cleaning device 200 of the present invention is formed with a cylindrical casing 210 to serve as a body. The casing 210 has a cylindrical shape having a top and a bottom having the same inner diameter and outer diameter, and is formed of a material capable of sufficiently maintaining airtightness as a tube capable of constantly inducing gas or liquid to be introduced. Above the upper center of the casing 210, a pipe 220 for inducing liquid or gas is disposed to a certain depth in the casing 210, and such a pipe 220 is one of the first guide vanes 230; Is coupled to the end of the side. In addition, the other end of the first guide feather 230 is firmly coupled to the inner surface of the cylindrical partition wall 250 having a height corresponding to the length of the pipe 220.

The first guide feather 230 is configured in the form of a blade to pivot the liquid or gas supplied in a streamline shape, one side is coupled to the pipe 220 and the other side is coupled to the inner surface of the partition 250 A plurality of pipes 220 and the partitions 250 are installed in the form. In addition, the partition wall 250 serves to separate and supply gas or liquid introduced into the casing 210 from each other, and has a diameter smaller than that of the casing 210 and has a cylindrical shape having an inner diameter and an outer diameter equal to those of the upper and lower portions thereof. It consists of. In addition, an injection nozzle 240 for injecting the supplied liquid or gas is formed at the outlet of the pipe 220.

One end of the second guide vane 260 is coupled to the outer surface of the partition 250. In addition, the other end of the second guide feather 260 is firmly coupled to the inner surface of the casing 210. Therefore, the first and second guide vanes 230 and 260, the pipe 220, and the partition wall 250 of the present invention are fixed to the upper inner surface of the casing 210. The second guide feather 260 is configured in the form of a blade to allow the flow of liquid or gas to be supplied in a streamlined form, one side is coupled to the outer surface of the partition wall 250 and the other side of the inner surface of the casing 210 A plurality of partitions 250 are installed between the casing 210 and the casing 210. At this time, the second guide vane 260 is inclined more than the first guide vane 230 so as to rotate in the same direction at a slower speed than the swirl flow formed along the first guide vane 230 and the casing ( It is installed between 210.

Therefore, in the absorption cleaning apparatus of the present invention, a high-speed swirl flow is formed through the first guide feather 230 installed near the center of the casing 210, and is installed near the inner surface of the casing 210. The second guide vane 260 is a swirl flow of a slower speed than the first guide vane 230 is formed. Then, the bottom surface of the casing 210 is open to serve as an outlet for discharging the supplied gas and liquid.

Hereinafter, the operation relationship of the absorption cleaning apparatus using the multi swirl flow configured as described above will be described in detail.

First, gas is supplied along first and second guide vanes 230 and 260 positioned on the casing 210. The gas supplied in this way forms a swirl flow while moving downward by the first and second guide vanes 230. At this time, a high speed swirl flow is formed through the first guide feather 230 installed near the center of the casing 210, and the second guide feather 260 installed near the inner surface of the casing 210. Through), a swirl flow of a slower speed than the first guide feather 230 is formed.

When gas flows while forming swirl flow along the inside of the casing 210, the liquid or gas is supplied through the pipe 220 disposed on the center of the casing 210. The liquid or gas supplied through the pipe 220 is in contact with the gas supplied while being injected through the injection nozzle 240 to form a swirl flow. At this time, the liquid or gas injected from the center of the casing 210 is mixed with the gas supplied at a high speed swirl flow along the first guide feather 230 is installed near the center of the casing 210, The diffusion is injected and mixed toward the gas supplied while forming the swirl flow along the second guide feather 260 at a slower speed than the first guide feather 230. That is, the liquid or gas injected through the injection nozzle 240 is diffused and sprayed toward the inner side surface of the casing 210 by the swirl flow formed along the first guide feather 230 and mixed more efficiently. At this time, when the gas and the gas are supplied and contacted, the mixture is uniformly mixed. When the gas and the liquid are supplied and contacted, the liquid absorbs and cleans the pollutants contained in the gas and discharges clean clean gas.

Absorption cleaning apparatus 200 of the present invention configured as described above is used for mixing, heating and giving up depending on the type of material supplied along the first and second guide feathers 230 and 260 and the pipe 220, respectively. do.

In addition, the absorption cleaning apparatus 200 of the present invention may be installed at the same inclination angle as the first guide feather 230 in installing the second guide feather 260 between the partition wall 250 and the casing 210. Even when the first and second guide vanes 230 and 260 are installed at the same inclination angle, the mixing may be more efficient than installing the guide vanes of one line. In addition, the absorption cleaning device 200 of the present invention may be configured such that as the casing 210 is enlarged, the cylindrical partition and the guide feather are additionally installed so that three or more swirl flows are formed.

Second Embodiment

The absorption cleaning device using the multi swirl flow described in this embodiment is the same as the absorption cleaning device described in the first embodiment except that one end is conical. Therefore, the same or similar reference numerals will be given to the same parts of the absorption cleaning apparatus using the multi swirl flow, and the description of the same reference numerals will be omitted.

6 is a cross-sectional view showing the configuration of the absorption cleaning apparatus using the multi-swirl flow according to the second embodiment of the present invention. As shown in FIG. 6, the casing 210a of the absorption cleaning apparatus 200a is a conical shape in which a cylindrical portion 210b having a constant inner diameter and an outer diameter is formed integrally with a conical portion 210c whose inner diameter and outer diameter become smaller. . The conical portion 210c serves to effectively mix the gas supplied along the first and second guide feathers 230 and 260 and the liquid or gas supplied through the pipe 220.

Third Embodiment

The absorption cleaning device using the multi swirl flow described in this embodiment is the same as the absorption cleaning device described in the first embodiment except that the casing is venturi type. Therefore, the same or similar reference numerals will be given to the same parts of the absorption cleaning apparatus using the multi swirl flow, and the description of the same reference numerals will be omitted.

7 is a cross-sectional view showing the configuration of the absorption cleaning apparatus using the multi-swirl flow according to the third embodiment of the present invention. As shown in FIG. 7, the casing 210d of the absorption cleaning apparatus 200b is upper and lower with respect to the first and second guide vanes 230 and 260 coupled to the inner side of the casing 210d. As it moves in the direction, it has a venturi shape that expands like a fallopian tube. On the outer surface of the casing 210d having such a shape, a pipe 220 penetrates the inner surface and supplies liquid or gas to the inside of the casing 210d. The venturi-type casing 210d raises and lowers the pressure of the gas to be supplied, thereby more uniformly stirring or mixing the gas supplied along the guide feathers 230 and 260 and the liquid or gas supplied through the pipe 220. can do.

As described in detail above, the present invention utilizes multi-swirl flows rotating at the same or different speeds along the central and inner side portions of the casing to more uniformly mix gases and / or liquids, or to warm and abandon the liquid. It works.

Although the technical details of the absorption cleaning apparatus using the multi-swirl flow of the present invention have been described with the accompanying drawings, this is illustrative of the best embodiments of the present invention and is not intended to limit the present invention.

It is also apparent to those skilled in the art that various modifications and imitations can be made within the scope of the appended claims without departing from the scope of the technical idea of the present invention.

1 is a cross-sectional view showing the configuration of the injection device using the swirl flow of the prior art,

Figure 2 is a plan view showing a coupling relationship of the guide feather of the injection device shown in Figure 1,

3 is a cross-sectional view showing the configuration of the absorption cleaning device using a multi-swirl flow in accordance with a first embodiment of the present invention,

4 and 5 are a plan view and an exploded perspective view showing a coupling relationship of the guide feather of the absorption cleaning device shown in FIG.

6 and 7 are cross-sectional views showing the configuration of the absorption cleaning apparatus using the multi-swirl flow according to the second and third embodiments of the present invention.

  ♠ Explanation of symbols on the main parts of the drawing ♠

200: absorption cleaner 210: casing

220: pipe 230: first guide feather

240: injection nozzle 250: bulkhead

260: second guide feather

Claims (4)

In the absorption cleaning device using a swirl flow for uniformly mixing the supplied liquid and / or gas, Hollow casing, A pipe extending inwardly from one end of the casing to inwardly inducing liquid or gas into the casing; A hollow partition wall having a height corresponding to the pipe and smaller in size than the casing; A plurality of first guide vanes for pivoting a plurality of liquids or gases provided and installed between the pipe and the partition wall in a streamlined form; A plurality of second guides for swirling a plurality of liquids or gases provided and installed between the partition wall and the casing to form a swirl flow of the same or slower speed than the swirl flow formed by the first guide feather. Feathers, and And an injection nozzle installed at the end of the pipe to inject liquid or gas into the casing. The absorption cleaning apparatus using multi swirl flow according to claim 1, wherein the casing is a cylindrical casing having a constant inner diameter and an outer diameter. The absorption cleaning device using multi swirl flow according to claim 1, wherein the casing is a conical casing in which a cylindrical portion having a constant inner diameter and an outer diameter and a conical portion whose inner diameter and outer diameter become smaller are integrally formed. According to claim 1, wherein the casing is absorbent cleaning apparatus using a multi-swirl flow, characterized in that the venturi-type casing that expands like a fallopian tube as it moves in the upper and lower directions relative to the first and second guide feathers.