KR102166393B1 - Device for preventing white plume - Google Patents

Abstract

The present invention relates to a white smoke prevention device, wherein the upper moving pipe 12 having an exhaust gas inlet 11 formed at one end passes through the exhaust gas inlet 11 and the outside air inlet 14, the entry port 12 and the blower 15 ), the other end is formed in the mixing chamber 13 connected only through the outside air inlet 12, and the outside air that has passed through the outside air inlet 12 meets the upper transfer pipe 12 to exchange heat with the exhaust gas, and the exhaust gas that has undergone heat exchange exits the upper transfer pipe 12 and the outside air Is mixed in the mixing chamber 13 passing through the blower 15.

Description

White smoke prevention device{DEVICE FOR PREVENTING WHITE PLUME}

The present invention relates to a white smoke prevention device.

The present invention relates to a white smoke prevention device. When hot humid air and low temperature outside air meet, some water vapor in the wet air condenses intensively in a small area and looks like a cloud, called white smoke. The maximum amount of moisture that air can contain varies depending on the temperature of the air. When saturated humid air of 68 degrees Celsius is discharged into the atmosphere of 25 degrees Celsius, the moisture air cools to the ambient temperature, reducing the maximum amount of moisture it can contain. Moisture in excess of the amount is condensed, making it appear as white smoke in the air when viewed from the outside.

The condensed moisture that has become white smoke evaporates and disappears into the atmosphere as it diffuses, but the evaporation time varies depending on the atmospheric humidity, so white smoke does not disappear easily on high humidity days.

Conventionally, the method of removing white smoke is a method of reducing the absolute amount of water vapor discharged into the atmosphere or a method of delaying condensation by dropping the relative humidity around the chimney.The former method is the method of condensing in the atmosphere and reducing the absolute amount of water that becomes white smoke. As a pre-reduction to suppress white smoke generation, the temperature of the humid air discharged through heat exchange is lowered to dehumidify. The latter method is to lower the relative humidity by mixing hot dry air or directly heating the exhaust gas.

Specifically, the method of removing white smoke is divided into reheating method, water cooling method, and air cooling method. The reheating method is a method of heating the discharge end by burning fuel, which has an excellent effect of reducing relative humidity, but the fuel cost increases and combustion gas is increased depending on the type of fuel. In some cases, itself is a source of water vapor.

The water cooling method is a method of performing heat exchange using a cooling pipe or cooling using a water spray. Among the methods for removing white smoke, it is an approach to reducing the absolute humidity. It can be configured in a small size, but it is uneconomical because it requires a cooling tower that cools the used cooling water again, and it is impossible to remove all white smoke using only water cooling, and reheating after water cooling is essential.

The air-cooling method cools the exhaust gas by heat exchange with the air in the atmosphere, and then reuses the heated air for heating/drying.The absolute humidity of the exhaust gas is lowered primarily through heat exchange, and then the hot dry air heated in the heat exchange process is heat-exchanged and discharged. Mix it with the final exhaust gas to add the effect of reducing relative humidity. Effective in removing white smoke, economical, no fuel consumption, no need for a cooling tower

There is a disadvantage in that additional installation costs are incurred in order to install a white smoke prevention device in an existing discharge facility that does not have a white smoke prevention device installed at the initial introduction stage. In addition, there is a disadvantage that it is difficult to completely remove white smoke only by reheating, water cooling, and air cooling.

The present invention has been devised to overcome the above-described disadvantages, and an object of the present invention is to provide a white smoke prevention device that can be easily applied to a facility where a white smoke generation device is not installed, and has a high smoke prevention effect.

In order to achieve the above object, the present invention provides a white smoke prevention device, wherein the top moving pipe 12 having an exhaust gas inlet 11 formed at one end passes through the exhaust gas inlet 11 and the outside air inlet 14 The other end is formed in the mixing chamber 13 connected only through the inlet 14 and the blower 15, and the outside air passing through the outside air inlet 14 meets the upper moving pipe 12 to exchange heat with the exhaust gas. After exiting the moving pipe 12, the outside air passes through the blower 15 and is mixed in the mixing chamber 13.

As the outside air passes through the outside air inlet 14, the temperature of the outside air rises, and the exhaust gas passing through the upper moving pipe 12 is cooled, and the relative humidity is maintained in a saturated state with psychrometric air having reduced absolute humidity.

The temperature of the mixed gas of the exhaust gas and the outside air that meet and mix in the mixing chamber may be adjusted to be located below the white smoke generation limit line in the temperature-moisture amount curve.

The blower may be capable of adjusting the amount of incoming outside air.

The upper moving pipe 12 may be such that a bundle made of a plurality is located between the outside air inlet and the blower.

According to the invention as described above, it has the effect of providing a device for preventing generation of white smoke that can be easily applied to existing discharge facilities without incurring a large cost.

1 to 7 are diagrams showing an embodiment according to the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 is a view briefly explaining a method for removing white smoke used in the present invention. The psychrometric air (A) meets at the outside air (a) and the heat exchanger and becomes psychrometric air (B) and outdoor air (b), respectively.The psychrometric air (A) is a high-temperature and high-humidity exhaust gas, and the psychrometric air B is cooled while passing through the heat exchanger to reduce absolute humidity The relative humidity of the furnace is saturated, the outside air a is the outside air existing in the atmosphere, and the outside air b is the outside air dried at high temperature through heat exchange.

The wet air (B) and the outside air (b) that have passed through the heat exchanger meet in the chimney (mixing chamber) and are mixed. As the high-temperature dry air (b) and the wet air (B) are mixed, the relative humidity is reduced to psychrometric air C.

The psychrometric air (D) is generated when psychrometric air C is discharged into the atmosphere and mixed directly with the outside air, and it is an object of the present invention to prevent white smoke from being generated when cooled in the process of mixing with the outside air.

Fig. 2 shows a graph analyzing the occurrence of white smoke, where the dry bulb temperature and the wet bulb temperature of the exhaust gas are 40 degrees Celsius, respectively, under the condition that they are discharged to the outside air at an outside temperature of 5 degrees Celsius.

When the exhaust gas is discharged, the state of the exhaust gas approaches the outside air and the moisture contained in the exhaust gas condenses and white smoke is generated in the air. That is, the amount of moisture in the exhaust gas corresponding to the difference in the amount of moisture that each air at 40 degrees Celsius and 5 degrees Celsius can contain (blue) is condensed to generate white smoke.

3 shows the situation of exhaust gas discharged after passing through the heat exchanger in the apparatus according to the present invention. By heat exchange between psychrometric air A and outdoor air a, it is moved to positions corresponding to psychrometric air B and outdoor air b in the graph, respectively. After that, when psychrometric air B and outside air b are mixed to become psychrometric air C, it moves to a yellow point on the graph. If the yellow point (c) is located below the white smoke generation limit line at the corresponding temperature, it is discharged without white smoke.

However, conventionally, in order to perform the operation as shown in FIG. 3, the exhaust gas must be supplied from the facility generating the exhaust gas and supplied to the white smoke prevention device, and a facility for sending the heat-exchanged outdoor air and exhaust gas back to the chimney must be provided.

To this end, in the past, a building including a facility for heat exchange outside the chimney/scrubber had to be newly built, and pipes for inlet and discharge of exhaust gas had to be built, so a huge cost was required.

4 and 5 illustrate an embodiment according to the present invention, and show an embodiment according to the present invention that is implemented without major structural changes to the existing exhaust gas emission facility. Figure 4 shows a location installed in the existing exhaust gas discharge facility, and Figure 5 shows the device in more detail. Unlike the prior art, the present invention has been proposed to be easily added to existing facilities.

Fig. 6 shows another embodiment. The white smoke removal apparatus according to the present invention allows high-temperature exhaust gas to be introduced from the lower end and low-temperature outdoor air from the side. At this time, the exhaust gas and the outside air are respectively introduced into the isolated passages so that only heat exchange occurs without mixing. In FIG. 5, the exhaust gas moves from the exhaust gas inlet 11 at the bottom to the mixing chamber 13 at the top through a plurality of top moving pipes 12, and the outside air is drawn in from the outside air inlet 14 on the side of the top moving pipe 12. It contacts the outside, makes heat exchange, and is introduced into the mixing chamber (13).

The top moving tube 12 can be formed in as many as possible to increase the surface area, and instead of reducing the cross section of the tube, a large number of top moving tubes 12 can be used, and the outlet of the top moving tube 12 is in the mixing chamber 13 It is connected and a blower 15 is installed in the center and the lower part of the mixing chamber. The outside air is introduced into the outside air inlet 14 on the side and contacts the outer surface of the upper moving pipe 12 to heat exchange and then moves to the mixing chamber 13.

Figure 6 shows another embodiment, as seen from the top of the mixing chamber, the blower 15 is located in the middle, and the drain water outlet of the upper moving pipe 12 is arranged around the blower 15, The outside air b that has entered through the blower 15 and the exhaust gas B that has passed through the upper moving pipe 12 meet in the mixing chamber 13.

Until entering the mixing chamber 13, the exhaust gas and outside air are not mixed and only heat exchange is performed.

7 shows a view from the side of the exhaust gas inlet (11). The drawings in the present specification are merely an embodiment and can be changed as much as possible within the technical concept. The outside air inlet 14 is separated from the exhaust gas inlet 11, but the upper moving pipe 12 through which the exhaust gas moves is made contactable with the outside air, so that heat exchange between the outside air and the exhaust gas occurs.

In Figure 7, the outside air inlet 14 is formed between the upper transfer tube 12 so that outside air flows through the upper transfer tube 12 and heat exchange occurs, and the upper transfer tube 12 is closed between bundles of the upper transfer tube 12 (12) Make the outside air flow only through the space.

If the operation of the device according to the present invention is described in more detail, the high-temperature exhaust gas at the exhaust gas inlet 11 corresponds to the exhaust gas A in the graph of FIG. 3, and the outside air before entering the outdoor air inlet 14 is shown in the graph. It corresponds to.

The place where the upper moving pipe 12 meets the outside air corresponds to the heat exchanger, and the exhaust gas exiting the upper moving pipe 12 becomes exhaust gas B by heat exchange, and the outside air in contact with the upper moving pipe 12 enters the mixing chamber 13 It comes and becomes the outside air b. In the mixing chamber, the exhaust gas B and the outside air b are mixed to become wet air C, and the sufficiently mixed exhaust gas C is discharged to the outside and becomes psychic air D.If it is located below the white smoke generation limit line, white smoke does not occur even if it is discharged to the outside.

The device according to the present invention can be easily applied to a currently used exhaust gas discharge device. That is, the exhaust gas discharge structure can be easily introduced by simply adding the device as shown in FIG. 5 to the existing device, and there is no need to install a separate chimney at the outlet of the mixing chamber. In other words, it is okay to demolish the existing chimney.

According to the present invention, a blower and a heat exchanger for introducing outside air are installed outside the existing exhaust gas discharge device, and the path of the exhaust gas is changed, mixed after heat exchange, and sent back to the chimney. Because it costs less and it is possible to control the temperature of the exhaust gas B and the outside air b by adjusting the speed of the blower, it is easy to adjust the exhaust gas C to be located below the white smoke generation limit.

11: exhaust gas inlet 12: upper transfer pipe
13: mixing chamber 14: outside air inlet
15: blower

Claims (4)

As a white smoke prevention device,
The exhaust gas inlet 11 is formed at one end so that the exhaust gas is introduced from the lower end of the white smoke prevention device, and the upper moving tube 12 consisting of a plurality of tubes erected perpendicular to the ground surface is
The other end is formed in the mixing chamber 13
The outside air flows through the outside air inlet 14 formed between the plurality of upper transfer pipes 12.
The outside air passing through the outside air inlet 14 meets the top moving pipe 12 to heat exchange with the exhaust gas, and the blower 15 formed at the bottom of the mixing chamber introduces the outside air passing through the outside air inlet 14 into the mixing chamber 13
The exhaust gas passes through the upper moving pipe 12 and is introduced into the mixing chamber 13, is mixed with outside air in the mixing chamber 13, and discharged to the outside.
The exhaust gas is introduced into the lower part of the vertically erected upper transfer pipe 12, meets the outside air in contact with the outer circumference of the upper transfer pipe 12, and is discharged to the outside through the mixing chamber at the top of the upper transfer pipe 12, and is easily added to the existing chimney. It is possible to do,
White smoke prevention device. According to claim 1, As the outside air passes through the outside air inlet (14), the temperature of the outside air rises, and the exhaust gas passing through the top moving pipe (12) is cooled to maintain the relative humidity in a saturated state with psychrometric air having a reduced absolute humidity. Device
The white smoke prevention device according to claim 2, wherein the temperature of the mixed gas of the flue gas and the outside air that meets and mixes in the mixing chamber is controlled to be located below the white smoke generation limit line in the temperature-moisture amount curve

The device of claim 3, wherein the blower is capable of adjusting the amount of incoming outside air.

Images