KR102139900B1 - White smoke removal device having a heat exchanger and a condensation filter unit and a white smoke removal method using the device - Google Patents

Abstract

The present invention relates to a white smoke removal apparatus including a heat exchanger and a condensation filter part, and a white smoke removal method using the same. More specifically, the white smoke removal apparatus comprises a heat exchanger (100), a condensation filter part (200) and a mixing part (300). Thus, heat is exchanged between exhaust air and outside air through the heat exchanger, the exhaust air and the outside air, which have exchanged heat, are cooled and mixed through the condensation filter part (200), and then, a collision is made between white smoke particles included in the cooled and mixed air to form condensate water and remove white smoke. Moreover, the exhaust air, from which the white smoke particles have been removed, and the outside air, which has exchanged heat through the heat exchanger, are mixed once again through the mixing part to increase temperature and reduce humidity in the end, thereby enabling the air, from which the white smoke has been removed, to be discharged to the outside to suppress environmental pollution, and a large amount of condensate water can be used as water for other purposes, and also, the apparatus can be reduced in size to one-fifth of an existing heat exchanger, which can lead to the elimination of limitations on installation and high economic efficiency.

Description

White smoke removal device having a heat exchanger and a condensation filter unit and a white smoke removal method using the device

The present invention relates to a white smoke removal apparatus having a heat exchanger and a condensation filter unit and a method for removing white smoke using the apparatus, and more specifically, heat exchanges the exhaust air and the outside air, and mixes the outside air and the exhaust air through the condensation filter unit. The present invention relates to a technology capable of removing white smoke by increasing the amount of condensate by removing many white smoke particles, and mixing the discharged white smoke air with the outside air heat-exchanged to lower the temperature rise and humidity.

Typically, white smoke is a phenomenon in which high-temperature, high-humidity water vapor generated in an industrial process meets external air with a relatively low temperature and condensation causes small droplets generated to scatter light to look like white excitation. To reduce or eliminate such white smoke, The heat exchange method or the filter method is applied to reduce or eliminate the white smoke.

However, when the heat exchange or filter method is used alone, the removal rate of the white smoke is not high, and the exhaust gas finally discharged contains fine dust, environmentally harmful substances, and the like, and thus it is difficult to remove visual pollution elements.

In other words, the conventional heating method is a method of reheating and using an auxiliary heat source at the exit of the chimney, but it is used in the industry according to the additional energy cost, and the cooling condensation method uses heat exchangers to condense moisture in the exhaust air. Although it is removed, the economic efficiency, which is large for the investment cost, decreases due to the large-capacity facility, and the simple mixed cooling type condenses and removes the temperature in the exhaust air by simply and mixed cooling the exhaust air with the exhaust air, but finally exhausts the exhaust. As the relative humidity of the air is 100%, additional condensation occurs due to contact with external air having a cooler temperature than the air that is discharged more, and white smoke is inevitable. This simple mixing method can reduce the white smoke phenomenon, It is impossible to remove, and the condition of the exhaust air finally discharged is greatly affected by the external air condition, and when the atmospheric humidity is high, such as in rainy weather, the humidity reduction has a very limited problem.

First, looking at the prior art,

Registration No. 10-1459963 (Special) The first heat exchanger, the second heat exchanger, the third to remove the odor contained in the exhaust gas having a large amount of moisture generated in facilities including industrial boilers, incinerators and industrial dryers The heat exchanger, the electrostatic precipitator and the filter unit are provided to remove the odor contained in the exhaust gas supplied inside, while condensing the moisture contained in the exhaust gas through heat exchange, and remove the odor in the exhaust gas by corona discharge generated from the electrostatic precipitator. Exhaust configured to remove the malodor contained secondarily and remove the malodor contained in the exhaust gas thirdly by using a filter unit having activated carbon impregnated with silver components to reduce the malodor contained in the exhaust gas discharged to the outside. An apparatus for reducing odor of gas, comprising: an exhaust gas inlet pipe for supplying exhaust gas containing odor and moisture; The exhaust gas inlet pipe is connected to one side to receive exhaust gas, and a water recovery pipe through which condensed water is condensed and discharged water is discharged is provided at the lower part, and the upper part is formed in an open type, and is constant inside. A space is formed, and the inside of the upper part is formed in a trapezoidal shape at the end so that the exhaust gas supplied from the exhaust gas inlet pipe can be evenly supplied to the upper part, and a dispersion plate having a plurality of perforations is provided, while the lower part is extended downwardly. A waste heat receiving portion formed to be inclined downward so as to narrow inward; In the upper portion of the waste heat receiving portion, a pair is provided to be spaced apart from each other, and a certain space is formed inside each, and each upper and lower portions are formed in an open type, but a plurality of through holes are formed to evenly distribute air on both sides. Spheres are provided, and the first and second case covers of a flat plate having a plurality of first through grooves penetrated in a symmetrical shape from one side to the other are provided in each of the opened upper and lower portions, respectively, and correspond to each. Between the first case cover, a plurality of vertically formed first waveplates having a symmetrical shape from one side to the other are provided with a first wave plate of 1 to 4 mm thick, corresponding to the first through groove, and each first wave plate A pair of first and second heat exchangers, each of which is coupled to the upper and lower ends of the first through groove; It is provided on one side of the second heat exchanger, the inside is formed through, the air is supplied from the outside to supply the inside of the second heat exchanger, inside the filter to remove foreign matter contained in the outside air supplied from the outside Is provided, between the filter and the second heat exchanger, an air supply unit having an air blowing fan to smoothly supply external air to the inside of the second heat exchanger; A supply duct connected to each side of the first heat exchanger and the second heat exchanger to supply air supplied from the second heat exchanger to the first heat exchanger; A plurality of layers are provided between the first heat exchanger and the second heat exchanger, and a certain space is formed inside each, and the top and bottom of each are formed in an open type, and the inside of each of the top and bottom is opened. The second case cover of a flat plate having a plurality of second through holes penetrated in a symmetrical shape from one side to the other side is provided, and the inside of each second case cover is stacked, from top to bottom for each stacked multistage. A circulating hole is formed symmetrically on one side and the other side so as to pass through the water, and a plurality of vertically formed between the corresponding second case covers, respectively, and the waveforms are symmetrical from one side to the other to correspond to the second through groove. A second wave plate having a thickness of 1 to 4 mm having a shape is provided, and each of the second wave plates includes a third heat exchanger in which upper and lower ends are respectively fitted into a second through groove; The third heat exchanger is provided with a pair connected to the upper and lower portions, respectively, on one side where the third heat exchanger is stacked, and supplies water supplied from the outside through the upper side to the inside of the third heat exchanger, and the inside of the third heat exchanger through the lower side of the third heat exchanger. A water pipe passing through and discharging water having an increased temperature; The upper and lower portions of the second heat exchanger are formed to be open and stacked, respectively, and a plurality of radix separators having a zigzag shape in an upward direction are formed in a plate shape and spaced apart, respectively. The upper end of the water separator is provided with a blocking opening bent downward; A mixing unit provided on the upper part of the water separator, the upper and lower parts being formed in an open type, and a dispersing port in which a plurality of holes are formed to evenly distribute air on the other side; An air duct connected to each other side of the mixing unit and the first heat exchanger to supply air from the first heat exchanger to the mixing unit; The upper and lower portions of the mixing portion are formed in an open type and stacked, and an inner side is provided with a dust collecting pole in which a plurality of cylindrical through holes are formed so that the exhaust gas supplied from the bottom passes through the upper portion, and the through hole of the dust collecting pole is provided. An electrostatic precipitator that is provided with a discharge electrode that is corona discharged between the precipitating electrode and the precipitating electrode by applying an electric field strength of 5 to 7 µm/cm, which is a high voltage by receiving a current of 3 to 15 kW/m 2 to the inside; A filter unit provided at the upper portion of the electrostatic precipitator and formed of activated carbon carrying 0.1 to 5% by weight of the nanoparticle silver to the total weight of the activated carbon; It is provided on the upper portion of the filter portion, the discharge portion is formed through the inside to discharge the exhaust gas passing through the filter portion to the outside; It is provided on the upper portion of the discharge portion, it is a technique for reducing the odor of exhaust gas comprising a cut-out having a cone shape so that rainwater does not flow into the discharge portion.

A waste heat receiving portion receiving exhaust gas through one side of Patent No. 10-1449339 (Special), the upper and lower portions are formed in an open type, and the lower portion is formed to extend downwards and inclined downward to narrow inwards; A plurality of pieces are sequentially stacked on the upper portion of the waste heat receiving portion to receive exhaust gas, and a certain space is formed inside each, and the top, bottom, left, and right are formed in an open type, and one side is respectively formed in each of the opened upper and lower parts. A plate-shaped case cover having a plurality of through-grooves penetrated in a symmetrical shape from the other side is provided, and a plurality of vertically formed between the corresponding case covers, each being corrugated from one side to the other to correspond to the through groove. A wave plate having a symmetrical shape is provided, and each wave plate includes a first heat exchanger, a second heat exchanger, and a third heat exchanger in which upper and lower ends are respectively fitted into through grooves; The upper and lower portions of the third heat exchanger are formed in an open type and stacked, and a plurality of radix separators having a zigzag shape in an upward direction formed in a plate shape are provided separately, and each of the radiator separators are provided. The upper end of the water separator is provided with a blocking opening bent downwardly, respectively; A mixing part having upper and lower portions formed on the upper part of the water separator and stacked, respectively; Each of the second heat exchanger and the third heat exchanger is provided to be coupled to one side, each of which is formed through the inside and receives air from the outside to supply the inside of the second heat exchanger and the third heat exchanger. A filter is provided to remove foreign substances and the like contained in external air supplied from the outside, and between each filter and the second heat exchanger and the third heat exchanger, external air is used for the second heat exchanger and the third heat exchanger. A first air supply unit and a second air supply unit, each of which is provided with a blower fan for smooth supply to the inside; A supply duct connected to each side of the first heat exchanger and the third heat exchanger to supply air received from the third heat exchanger to the first heat exchanger; A recovery duct connected to the other side of the first air supply of the second heat exchanger to recover outside air passing through the second heat exchanger; Air and exhaust gas having a multi-layer stacked structure comprising air ducts connected to the other side of the supply duct provided on one side of the first heat exchanger and the other side of the mixing section to supply external air passing through the first heat exchanger to the mixing section. It is a technology related to the heat exchanger.

The above-described prior art mainly describes that the exhaust air and the outside air are exchanged through a heat exchange method, and then discharged.

However, the prior art describes that it is possible to remove condensate, fine dust, and odor through a heat exchanger. However, since the substantially discharged air still contains white smoke, it has a problem in that it cannot be completely removed.

Accordingly, an object of the present invention is to move the exhaust air and the outside air to heat exchange and heat exchange the outside air to the mixing unit side, and heat exchanged exhaust air is mixed with the outside air again to cool the white smoke particles contained in the exhaust air. After generating a larger amount of condensed water by generating collisions, the white smoke particles are removed and then moved to the mixing section, and finally, through the method of mixing the heat exchanged outdoor air and the exhaust air from which the white smoke particles have been removed, finally to the outside. A mixture of the outside air and the exhaust air is mixed several times, and the temperature rise and humidity can be lowered to remove the white smoke. It was accomplished with a technical task.

As a technical idea for achieving the above object, a space is provided inside, and the exhaust air inlet 120 and the exhaust air inlet (120) connected to the exhaust pipe 80 formed so that the exhaust air (b) is introduced to the outside side On the other side where 120) is formed, waste heat is discharged to the other side where the first outside air inlet 130 and the outside air inlet 120 and the first outside air inlet 130 are formed so that the outside air w is input. The waste heat exhaust port 140, the waste heat exhaust port 140 is formed to be spaced apart from the heat exchanged outside air (w1) is formed to be discharged toward the mixing unit 300, the outside air exhaust port 150 and the condensation filter unit 200 ) Is connected to the connection part 210 of the heat exchanger 100 consisting of a movement path 160 through which the heat exchanged exhaust air (b1) moves; A space is provided inside, and the connection part 210 connected to the moving path 160 is installed on the outside side, and the fine dust contained in the heat exchanged exhaust air (b1) spaced apart from the rear of the connection part 210 To remove the filter 220 and the white smoke particles contained in the heat exchanged exhaust air (b1) that is installed spaced apart from the rear of the filter 220 flowing from the moving path 160 to form condensate It is located on the space with the mr 230 and a second outside air inlet 240 for allowing the outside air (w) to enter and cool with the heat exchanged exhaust air (b1) on the lower side. A condensation filter unit 200 composed of a cooling space 250 in which cooling is performed when the exhaust air b1 exchanged between the filter 220 and the demister 230 meets with the external air w inputted; It is installed to be spaced apart from the condensation filter unit 200, and intakes the heat exchanged outside air (w1) discharged from the heat exchanger (100) and the exhaust air (b2) from which the white smoke particles are removed from the condensation filter unit (200). Mixing unit 300 to receive and mix to increase the temperature and lower the humidity to discharge; It is characterized by consisting of.

In the white smoke removal device, a cooling fan installed at one side or close to the outside of the heat exchanger 100 and connected to the first and second outside air inlets 130 and 240 to suck and cool the outside air w. 180) is characterized by being configured.

The white smoke removal device, which is installed on one side or close to the outside of the condensation filter unit 200, discharges the exhaust air (b2) that has been cooled to remove the white smoke particles, and sucks the heat exchanged exhaust air (b1) therein. It is a technical feature that the exhaust fan 270 is configured to cause a collision between the included white smoke particles.

The second outside air inlet 240, the fine dust of the heat exchanged exhaust air (b1) is removed and before removing the white smoke particles, the exhaust air (b1) heat-exchanged in the cooling space 250, the outside air (w) It is characterized in that it is configured to be located in front of the lower portion of the cooling space 250 and the demister 230 so as to be cooled and mixed by.

The demister 230 is composed of one or more, the second outside air inlet 240 is a technical feature that is formed to correspond to the number of the demister 230.

Using the white smoke removal device as described above, the input step (S10) for introducing the exhaust air (b) and the outside air (w), respectively; A heat exchange step (S20) in which the exhaust air (b) and the outside air (w) exchange heat inside the heat exchanger (100); The heat exchanged outdoor air (w1) is moved to the mixing unit 300 side, and the heat exchanged exhaust air (b1) is moved to the condensing filter unit 200 side (S30); After the heat-exchanged exhaust air (b1) is moved to the inside of the condensation filter unit 200, it is mixed and cooled with the external air (w) being input, and causes collision between the white smoke particles to remove the white smoke particles and form condensate, A first white smoke removal step (S40) in which the exhaust air (b2) from which the white smoke particles have been removed is moved toward the mixing part (300); A second white smoke removal step (S50) of mixing the outside air (w1) heat exchanged in the moving step (S30) with the exhaust air (b2) from which the white smoke particles have been removed, and raising the temperature and lowering the humidity; It is made of a technical feature.

In the input step (S10) and in the first white smoke removal step (S40), the cooling fan 180 and the exhaust fan 270 are respectively or independently operated to input and discharge ships and external air (b, w), The technical feature is to remove fine dust, cooling, and white smoke particles from the heat exchanged exhaust air (b2).

According to the apparatus for removing white smoke having a heat exchanger and a condensing filter according to the present invention and a method for removing white smoke using the apparatus, while maintaining the purpose of removing the white smoke as it is, the exhaust air exchanged by hitting the heat exchanger of ship and external air It can be used for a variety of other purposes, and heat exchanged exhaust air passes through the condensation filter to cause fine dust and white particles to collide to form more condensate, and finally mix the heat exchanged outside air with the exhaust air from which the white smoke has been removed. By increasing the temperature and reducing humidity and exhausting the air from which the white smoke has been removed, it is possible to suppress environmental pollution, and a large amount of condensate can be used as other water, as well as being used as a conventional heat exchanger 1/5 It is a useful invention with no restrictions on installation that can be manufactured to be reduced in size and has high economic efficiency.

1 is a block diagram showing a preferred embodiment of the present invention
2 is a block diagram showing a preferred embodiment of the heat exchanger of the present invention
3 is a block diagram showing a preferred embodiment of the condensation filter unit of the present invention
4 is a view showing the flow of the exhaust air and the outside air of the present invention
Figure 5 is an operating state showing a preferred embodiment of the present invention
6 is a flow chart showing a preferred embodiment of the present invention
7 is a view showing a preferred embodiment of the present invention
8 is a view showing a comparison between the present invention and the prior art
9 is a view showing the temperature and humidity comparison of the present invention and the prior art

The present invention, in more detail, heat exchanges the exhaust air and the outside air, and mixes the outside air and the exhaust air through the condensation filter to remove more white smoke particles to increase the amount of condensate, and the outside air heat exchanged with the discharged white smoke air Provided is a white smoke removal device having a heat exchanger and a condensation filter unit capable of removing white smoke by mixing the mixture once more and lowering the temperature and humidity, and a method for removing white smoke using the same.

Hereinafter, a preferred configuration and operation of the present invention for achieving the above object with reference to the accompanying drawings will be described with reference to FIGS. 1 to 7 as follows.

First, as shown in FIG. 1, the present invention is mainly composed of a heat exchanger 100, a condensation filter unit 200, a mixing unit 300, and a connecting pipe 400.

① Heat exchanger (100)

The heat exchanger 100 is provided with a space therein as shown in FIG. 2, in the case of the space, exhaust air introduced through the exhaust air inlet 120 and the first external air inlet 130 to be described below ( It is a space for b) and external air (w) to be mixed and exchanged.

Here, the inside of the heat exchanger 100 is formed of a cross member 101 so that the exhaust air (b) and the external air (w) to be intersected with each other, the exhaust air inlet 120 and the first outside air After each of the exhaust air (b) and the outside air (w) introduced into the air inlet 130 are cross-exchanged and heat-exchanged, they are formed to be discharged in different directions.

In addition, although the cross member 101 is not shown, the end may be formed to be extended so as to be completely connected to the inlet of the exhaust air (b) and the outside air (w), it is limited as an embodiment of the present invention No.

As illustrated in FIGS. 1 and 2, the exhaust air inlet 120 is connected to an exhaust pipe that is formed so that the exhaust air (b) is input to the external one side, and the exhaust air (b) moving from the exhaust pipe is input. It is configured to be introduced into the space of the heat exchanger 100.

At this time, the exhaust air (b) may be a variety of exhaust air depending on the place where the white smoke removal device of the present invention is installed.

The first outside air inlet 130 is configured on one side of the heat exchanger 100, but is formed on the other side where the exhaust air inlet 120 is formed so that the outside air (w) is introduced, and the outside air (w) It is a configuration for heat exchange with the exhaust air (b) in the space of the heat exchanger 100 by putting it in.

On the other hand, after heat exchange from the exhaust air (b) and the outside air (w) on the upper side of the heat exchanger 100, a waste heat discharge port 140 through which the heat exchanged air is discharged is formed, and the waste heat discharge port 140 ) Is a configuration to allow the heat-exchanged air to discharge waste heat for use for other purposes.

In addition, the upper portion of the heat exchanger 100 is formed to be spaced apart from the waste heat outlet 140, and the external air outlet (w1) heat-exchanged is formed to be discharged toward the mixing unit 300 side.

The external air outlet 150 is configured to be connected to the mixing unit 300 through the connecting pipe 400.

Here, the exhaust air inlet 120 and the first external air inlet 130 may be formed as one or a plurality, in the present invention is shown to be formed as each one.

It is configured on one side of the heat exchanger 100, the exhaust air inlet 120, the first outside air inlet 130, the waste heat outlet 140, the outside air outlet 150 is formed on the other side of the condensation filter unit ( 200 is connected to the connection portion 210 of the 200 is configured to move the heat exchanged exhaust air (b1) is moved.

That is, as shown in FIG. 1, the movement path 160 provides a space for the heat exchanged exhaust air b1 to move toward the condensation filter unit 200, wherein the movement path 160 is separately The connecting pipe 400 is not configured and is directly connected to one side of the condensation filter unit 200.

In addition, although not shown, the exhaust air (b) and the outside air (w) are heat-exchanged to form condensate at the bottom of the heat exchanger 100. At this time, a condensate outlet is further formed to discharge the condensed water. A fresh water member may be configured to store condensate spaced apart from the bottom of the condensate outlet. (not shown)

On the other hand, as described above, the heat exchanger 100 is installed on one side or close to the outside, and is connected to the first and second external air inlets 130 and 240 to cool the cooling fan 180 by sucking the external air w. ) Is configured, it is possible to cool the general external air (w) before being introduced into the heat exchanger (100) so that its temperature is lower, and can be introduced into the heat exchanger (100), as well as the exhaust air It is configured to maintain the same input speed of (b) so that uniform heat exchange can be achieved.

In other words, the cooling fan 180 is not only for the purpose of simply lowering the temperature of the outside air (w), but to input the outside air (w) at the same speed as that of the exhaust air (b). You will be able to achieve two purposes.

In addition, the cooling fan 180 is configured to be close to or connected to the first external air inlet 130 of the heat exchanger 100, and is composed of one or a plurality, so that the cooling efficiency of the first external air (w) Can be further maximized.

In addition, since the heat exchanger is used together with the condensation filter unit 200 to be described below, it can be installed and used in 1/5 the size of a heat exchanger used in the related art, thereby increasing economic efficiency without restrictions on installation. have.

② Condensation filter unit (200)

The condensation filter unit 200 is provided with a space therein, as shown in FIGS. 1, 3, and 4, a connection unit 210, a filter 220, a demister 230, and a second external air inlet 240 And a cooling space 250.

The connection part 210 is configured to be connected to the movement path 160 of the heat exchanger 100, as shown in FIG. 1 or 3, and is formed so that an external one side protrudes in one direction and the movement path 160 and The connection is made.

In the case of the connection portion 210, the exhaust air (b1) heat-exchanged from the movement path 160 serves as a passage for movement.

The filter 220 is configured inside the condensation filter unit 200 as shown in FIG. 3, but is installed at a distance from the rear of the connection unit 210 to fine dust contained in the heat exchanged exhaust air b1. It is configured to be removed, and the filter 220 is used by applying a conventional product that is commonly used for removing fine dust, and the number thereof is configured and used as necessary.

Filtering fine dust and foreign substances contained in the exhaust air (b1) heat-exchanged through the configuration of the filter 220, and the filtered exhaust air is introduced through the second outside air inlet 240, the outside air (w) And can be cooled and mixed.

The demister 230 is installed spaced apart from the rear of the filter 220 as shown in Figure 1 or 3, the white smoke particles contained in the heat exchanged exhaust air (b1) flowing from the moving path 160 It is configured to remove and form condensate.

At this time, the demister 230, after the heat-exchanged exhaust air (b1) and the outside air (w) is cooled and mixed, the air is moved to the demister 230 side, white smoke by the demister 230 The condensed water is formed through collision between the particles and the white smoke particles, so that the condensed water can be discharged to the lower portion of the demister 230, and the formed condensed water can be used for various other purposes.

Here, the demister 230 may be formed of one or more, if more demister 230 is configured, it is possible to remove a lot of white particles, the air finally discharged from the mixing unit 300 The white smoke can be completely removed up to 95%, and the demister 230 is shown to be composed of two.

The second outside air inlet 240 is configured to allow the outside air (w) to be introduced into the lower one side to meet and cool the heat exchanged exhaust air (b1) as shown in FIG. 1 or FIG. It is a configuration that is input to allow the heat exchanged exhaust air (b1) moved through the movement path (160) to meet the external air (w) introduced through the second external air inlet (240).

At this time, the second outside air inlet 240 is formed to be the same according to the number of the demister 230, the present invention is shown that the demister 230 is composed of two, the second outside air The air inlet 240 is also shown to be composed of two.

In addition, the second outside air inlet 240, the fine dust of the heat exchanged exhaust air (b1) is removed and before removing the white smoke particles, the exhaust air (b1) heat-exchanged in the cooling space 250 is introduced to the outside air ( It is configured to be located in the lower portion of the cooling space 250 and in front of the demister 230 to be cooled and mixed by w).

On the other hand, the cooling space 250 is located on the space as shown in Figures 1, 3, 4, the filter 220 and the demister 230 heat exchanged between the exhaust air (b1) and the input The outside air (w) is formed to meet and cool.

Here, the white smoke removal device, which is installed on one side or close to the outside of the condensation filter unit 200 to cool, discharges the exhaust air (b2) from which the white smoke particles have been removed, and sucks the heat exchanged exhaust air (b1). The discharge fan 270 is configured to cause collision between the white smoke particles contained therein, and the collision between the white smoke particles and the white smoke particles contained in the heat exchanged exhaust air b1 is maximized through the operation of the discharge fan 270 As it forms more condensate, white smoke can be removed.

At this time, the discharge fan 270 may also be configured as one or more as needed.

③Mixing unit (300)

The mixing unit 300 is installed to be spaced apart from the condensation filter unit 200 as shown in FIGS. 1, 3, and 4, and the heat exchanged external air w1 discharged from the heat exchanger 100 and the It is configured to receive and mix the exhaust air (b2) from which the white smoke particles have been removed from the condensation filter unit (200) to increase the temperature and lower the humidity to discharge.

At this time, the external air (w1) heat-exchanged from the external air discharge port (150) flows through and through the connecting pipe (400) for the inflow of exhaust air (b2) from which the white smoke particles have been removed through the condensation filter unit (200). Connection is made, the mixing unit 300 is finally mixed with the external air (w1) heat exchanged and the exhaust air (b2) from which the white smoke particles have been removed is mixed to lower the temperature rise and humidity to discharge the air to the outside And removes up to 95% of white smoke to form and discharge it so that it cannot be seen with the naked eye.

④Connector(400)

The connection pipe 400 allows the first outside air inlet 130 and the second outside air inlet 240 to be interconnected, as shown in FIGS. 1, 4, and 5, and the outside air outlet 150 It is configured to connect the mixing unit 300 and connect the exhaust air b2 from which the white smoke particles are removed to the rear of the condensation filter unit 200 so as to be moved toward the mixing unit 300.

That is, the connecting pipe 400 is formed in a tube shape such as a normal pipe, and a moving space in which gas, fluid, etc. can be moved is provided.

In addition, although not shown, holes in each heat exchanger 100 and condensation filter unit 200 so that condensed water formed when heat exchange and condensation filter unit 200 is removed from the heat exchanger 100 can be discharged. After forming the, it may be used to connect the hole and the connecting pipe 400.

The method for removing white smoke using the white smoke removal device of the present invention configured as described above is an input step (S10), a heat exchange step (S20), a moving step (S30), and a first white smoke removal step as shown in FIGS. (S40), a second smoke removal step (S50).

The input step (S10) is a step of inputting the exhaust air (b) and the external air (w), respectively, as shown in Figure 4, as shown in Figure 4, the exhaust air inlet 120 connected to the exhaust pipe of the industrial site ) Is a step in which the exhaust air (b) input from the air and the external air (w) cooled by the cooling fan 180 are input from the first external air inlet 130.

On the other hand, the heat exchange step (S200), as shown in Figure 5, the heat exchange of the exhaust air (b) and the outside air (w) in the interior of the heat exchanger 100, the high of the exhaust air (b) The temperature and the low temperature of the outside air (w) meet each other and cross-exchange heat exchange, so that the heat exchanged outside air (w1) discharged to the outside air outlet (150) has a higher temperature than the first introduced outside air (w) , The heat-exchanged exhaust air (b1) has a lower temperature than the first input exhaust air (b), and condensed water is formed through the heat exchange, and the condensed water can be used for a separate use if necessary.

In the moving step (S30), as shown in FIGS. 4 and 5, the external air (w1) having the temperature higher than that of the first external air (w) is moved to the mixing unit 300 side, and the heat exchanged exhaust air (b1) has a lower temperature than the exhaust air (b) input from the exhaust pipe and moves to the condensation filter unit 200 side.

The first white smoke removal step (S40), after the heat-exchanged exhaust air (b1) is moved to the interior of the condensation filter unit 200 in Figure 5, the outside air to be introduced from the second outside air inlet 240 is introduced It is mixed with air (w) and cooled, causing collision between the white smoke particles contained in the heat exchanged exhaust air (b1) to form white smoke particles and forming condensate, and the exhaust air (b2) from which the white smoke particles have been removed is a mixing part (300). ) Side.

At this time, the coarse weight formed through the collision between the white smoke particles maximizes the collision between the white smoke particles and the white smoke particles through the discharge fan 270, which means that more condensate is formed than the conventional one, that is, the white smoke particles are removed a lot. It is possible to remove the white smoke particles more.

On the other hand, in the second white smoke removal step (S50), as shown in Figure 5, the external air (w1) heat-exchanged in the moving step (S30) and the white smoke particles are removed in the first white smoke removal step (S40). After each of the exhaust air (b2) is introduced from the mixing unit (300), the mixed air is introduced to each other to prevent the occurrence of white smoke again due to the temperature difference that occurs when contacting the outside air when discharged to the outside. When mixing the exhaust air (b2) from which the white smoke has been removed and the external air (w1) heat-exchanged, the temperature rises and lowers the humidity to a temperature similar to the external temperature, and finally discharged to the outside.

At this time, in the input step (S10) and in the first white smoke removal step (S40), the cooling fan 180 and the exhaust fan 270 are operated individually or independently, so that the input of the ship and the outside air (b, w) It is possible to remove fine dust, cooling, and white smoke particles of the exhaust air (b2) that is discharged and heat exchanged.

In other words, as illustrated in FIG. 8, as an example,

The first exhaust air (b) is injected at 62 degrees 0.1252KG/KG, and the outside air (w) is injected at -5 degrees 0.002KG/KG to exchange heat in the heat exchanger 100, and then from the heat exchanger 100 The heat exchanged outside air becomes 48 degrees 0.002KG/KG and moves toward the mixing unit 300, and the exhaust air (b1) heat exchanged from the heat exchanger becomes 55 degrees and moves toward the condensation filter unit 200.

Here, the heat exchanged exhaust air (b1) is again mixed with the external air (w) of -5 degrees 0.002KG/KG, condensed water is formed by collision between the white smoke particles, and finally the exhaust air (b2) from which the white smoke particles have been removed is The temperature decreases and the weight decreases to 0.996KG/KG at 13.4 degrees and moves to the mixing part 300. The reason why the weight of the exhaust air (b2) from which the white smoke particles have been removed is reduced is that condensate is formed to decrease as the white smoke is removed. The exhaust air (b2) from which the white smoke has been removed is moved to the mixing part (300) and mixed with heat exchanged outside air (w1) of 0.002KG/KG at 48 degrees, and finally discharged to the outside. Figure 0.0088KG / KG weight and relative humidity by being discharged to 74%, it is possible to remove the white smoke 95%.

In addition, as shown in FIG. 9, the conditions of the input air (b) and the external air (w) are the same, and when mixed in the other condensation filter unit 200, other conditions can be varied.

100: heat exchanger 101: cross section
120: exhaust air inlet 130: the first outside air inlet
140: waste heat outlet 141: damper
150: outside air outlet 160: moving 180: cooling fan
200: condensation filter unit
210: Connection 220: Filter 230: Thermistor
240: second outside air inlet 250: cooling space 270: exhaust fan
300: mixing unit
b: exhaust air w: outside air b1: heat exchanged exhaust air
w1: Heat exchanged outside air b2: Exhaust air with white smoke particles removed
S10: input step S20: heat exchange step
S30: Moving step S40: First white smoke removal step
S50: Second white smoke removal step

Claims (7)

A space is provided inside, and the exhaust air inlet 120 is connected to the exhaust pipe 80 formed so that the exhaust air (b) is injected on the outer side, and the outside air is provided on the other side where the exhaust air inlet 120 is formed. w) the first outside air inlet 130 is formed to be input, the exhaust air inlet 120 and the first outside air inlet 130 is formed on the other side of the waste heat discharge outlet 140 is discharged waste heat, and the waste heat The external air outlet (w1) formed to be spaced apart from the outlet 140 and heat-exchanged is connected to the connection portion 210 of the condensation filter unit 200 and the external air outlet 150 formed to be discharged toward the mixing unit 300 Heat exchanger 100 consisting of a moving path 160 through which the exhaust air (b1) is moved;
A space is provided inside, and the connection part 210 connected to the moving path 160 is installed on the outside side, and the fine dust contained in the heat exchanged exhaust air (b1) spaced apart from the rear of the connection part 210 To remove the filter 220 and the white smoke particles contained in the heat exchanged exhaust air (b1) that is installed spaced apart from the rear of the filter 220 flowing from the moving path 160 to form condensate It is located on the space with the mr 230 and a second outside air inlet 240 for allowing the outside air (w) to enter and cool with the heat exchanged exhaust air (b1) on the lower side. A condensation filter unit 200 composed of a cooling space 250 in which the exhaust air b1 exchanged between the filter 220 and the demister 230 and the external air (w) being input meet and are cooled;
It is installed to be spaced apart from the condensation filter unit 200, and intakes the heat exchanged outside air (w1) discharged from the heat exchanger (100) and the exhaust air (b2) from which the white smoke particles are removed from the condensation filter unit (200). Mixing unit 300 to receive and mix to increase the temperature and lower the humidity to discharge; White smoke removal device having a heat exchanger and a condensation filter, characterized in that consisting of.
According to claim 1,
The white smoke removal device,
It is installed on one side or close to the outside of the heat exchanger 100, and is connected to the first and second outside air inlets 130 and 240 to form a cooling fan 180 that sucks and cools outside air w. A white smoke removal device having a heat exchanger and a condensation filter unit characterized in that.
According to claim 1,
The white smoke removal device,
It is installed on one side or close to the outside of the condensation filter unit 200 to discharge the exhaust air (b2) that has been cooled to remove the white smoke particles, but sucks the heat exchanged exhaust air (b1) to collide between the white smoke particles contained therein. A white smoke removal device having a heat exchanger and a condensation filter, characterized in that the discharge fan (270) is configured to cause the discharge.
According to claim 1,
The second outside air inlet 240,
The cooling space so that fine dust of the heat-exchanged exhaust air (b1) is removed and before the white smoke particles are removed, the exhaust air (b1) heat-exchanged in the cooling space (250) is cooled and mixed by the external air (w). A white smoke removal device having a heat exchanger and a condensation filter, characterized in that it is configured to be positioned at the bottom of the 250 and in front of the demister 230.
According to claim 1,
The demister 230 is composed of one or more,
The second outside air inlet 240 is a white smoke removal device having a heat exchanger and a condensation filter, characterized in that formed to correspond to the number of the demister (230).
Claims 1 to 5 of any one of the white smoke removal device is used,
An input step (S10) of inputting exhaust air (b) and external air (w), respectively;
A heat exchange step (S20) in which the exhaust air (b) and the outside air (w) exchange heat inside the heat exchanger (100);
The heat exchanged outdoor air (w1) is moved to the mixing unit 300 side, and the heat exchanged exhaust air (b1) is moved to the condensing filter unit 200 side (S30);
After the heat-exchanged exhaust air (b1) is moved to the inside of the condensation filter unit 200, it is mixed and cooled with the external air (w) being input, and causes collision between the white smoke particles to remove the white smoke particles and form condensate, A first white smoke removal step (S40) in which the exhaust air (b2) from which the white smoke particles have been removed is moved toward the mixing part (300);
A second white smoke removal step (S50) of mixing the outside air (w1) heat exchanged in the moving step (S30) with the exhaust air (b2) from which the white smoke particles have been removed, and raising the temperature and lowering the humidity; Method for removing white smoke using a white smoke removal device having a heat exchanger and a condensation filter, characterized in that consisting of.
The method of claim 6,
In the input step (S10) and in the first white smoke removal step (S40), the cooling fan 180 and the exhaust fan 270 are operated individually or independently,
Removal of white smoke using a white smoke removal device having a heat exchanger and a condensation filter unit, characterized by removing fine dust, cooling, and white smoke particles of the exhaust air (b2), which is input and discharged from the exhaust air and external air (b, w), and heat exchanged. Way.

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