KR101270900B1 - Waste heat and water collecting apparatus using reducing white smoke - Google Patents

Abstract

PURPOSE: An apparatus for reducing the generation of white smoke and collecting waste heat and water using the same is provided to easily reduce the generation of white smoke and to reduce water consumption. CONSTITUTION: An apparatus for reducing the generation of white smoke and collecting waste heat and water using the same includes an exhaust gas inputting tube(4), a water collecting unit(10), a sensible heat exchanger(20), a first latent heat exchanger(30), a second latent heat exchanger(40), a gas-water separator(50), a discharging unit(60), a circulating duct(70), and a mixing duct(80). The circulating duct supplies the external air of the second latent heat exchanger to the sensible heat exchanger. The mixing duct supplies external air to the discharging unit. The lower board of the sensible heat exchanger is combined with the upper side of the upper board of the water collecting unit. A wave-shaped heat exchanging hole is arranged at the upper side of the lower board. A plurality of wave-shaped divided boards is combined, and an exhaust conduit is formed on the wave-shaped heat exchanging hole. Exhaust gas passes through the divided boards. Flat covers for the heat exchanging hole are arranged at the upper and lower sides of the heat exchanging hole. Lateral boards with an air inlet and an air outlet are arranged on both outer circumferences of the heat exchanging hole. The upper board of the sensible heat exchanger is arranged at the upper side of the lateral boards.

Description

Reduction of white smoke and waste heat recovery and water recovery apparatus using the same {Waste heat and water collecting apparatus using reducing white smoke}

The present invention relates to a reduction in white smoke generation and waste heat recovery and water recovery apparatus using the same, and more particularly, to recover waste heat without directly discharging the high-temperature exhaust gas generated in equipment such as industrial boilers, incinerators and dryers. It saves energy by condensing the moisture contained in the exhaust gas so that the water can be recovered and reused, while removing the moisture contained in the exhaust gas to reduce the occurrence of white smoke that occurs mainly in winter so that the exhaust gas goes to the outside. The present invention relates to a reduction in white smoke generation to remove white smoke, which looks like white smoke when discharged, and a waste heat recovery and water recovery device using the same.

In general, in places such as steel mills, direct cooling devices are used to cool intermediate materials or facilities, and direct cooling devices typically use water as cooling water. In this case, water vapor is inevitably generated.

The steam generated as described above is discharged to the outside so as not to interfere with the operation, and the exhaust gas discharged to the outside contains a large amount of moisture, so that a white smoke phenomenon appears as white smoke when discharged to the chimney.

At this time, the white smoke phenomenon occurs when the heated humid air is mixed with cold air in the air and is cooled below the dew point. The white smoke occurs in an environment where the air is cooled under the condition of the upper side of the 100% saturation curve of the wet air diagram. In winter, the whites are more severe.

In addition, although the white lead is not a pollutant, it is not only seen as a visual burden burdening visually when viewed from the outside, but also due to cooling below the dew point of the white lead, excessive water droplets are formed and fall around the chimney. There was a problem such as creating an unpleasant feeling or falling ice on the road around in winter.

Meanwhile, in order to solve the above problems, a refrigerant compressor for compressing a refrigerant at high temperature and high pressure, and a refrigerant discharged from the refrigerant compressor circulate inside to release heat to external exhaust air to form a liquid at room temperature and high pressure. The heating unit, the refrigerant discharged from the heating unit is introduced into the refrigerant tube formed to include an expansion tube, and the refrigerant is installed in the lower portion of the heating unit and passed through the refrigerant tube in a low temperature low pressure liquefied state therein Techniques including a cooling unit which is formed to circulate and are vaporized to cool external exhaust air to condense water vapor in the exhaust air have been known as in Patent Publication No. 10-1197283.

However, the above technique is only to prevent the white smoke phenomenon, there is a problem that can not be used to recover the waste heat and reuse or recover the moisture contained in the exhaust gas again.

In addition, the above-described technology is a complicated configuration, a lot of costs to manufacture the device, there is a problem in that the additional cost is also generated to operate the device, frequent maintenance and repair.

Therefore, there is a need for reducing the generation of white smoke and waste heat recovery and water recovery apparatus using the same to solve the conventional problems as described above.

Patent Registration No. 10-1197283

The present invention has been invented to solve the problems of the prior art as described above, with a simple structure does not discharge the high-temperature, humid exhaust gas discharged from the facility into the atmosphere as it is, to recover the waste heat to recover energy as a heat source such as heating The purpose is to reduce the wasted energy by reuse.

In addition, another object of the present invention is to provide a reduction in smoke generation and waste heat recovery and water recovery apparatus using the same to reduce the consumption of water used as cooling water by condensing and recovering the water contained in the exhaust gas in a large amount have.

Another object of the present invention is to reduce the white smoke generated by condensing and recovering the moisture contained in the exhaust gas in a large amount for the generation of white smoke in the winter, waste heat recovery and water recovery device using the same To provide.

In order to achieve the above object, the present invention is the exhaust gas inlet pipe for supplying the exhaust gas containing water vapor, and the exhaust gas is supplied through the exhaust gas inlet formed on one side connected to the exhaust gas inlet pipe, It has a water recovery portion having a flat water recovery upper plate and a water recovery hole penetrating the inner side, and is provided in the upper portion of the water recovery portion, the upper portion of the water recovery upper plate is penetrated inside the water recovery upper plate The lower plate having a space is coupled to each other, and the upper portion of the lower plate is provided with a corrugated heat exchanger in which a plurality of wave plates that are corrugated to be perpendicular to the lower plate are combined in a symmetrical wave form to form exhaust pipes through which exhaust gas can move between the wave plates. In the upper and lower parts of the corrugated heat exchange port, through-holes are formed to correspond to the exhaust pipe so that exhaust gas can move. A plate heat exchanger cover is provided, and the outer circumferential surface of the corrugated heat exchanger is provided with side plates having air inlets and air outlets formed on both sides thereof, and an upper plate formed therein with a space penetrating therein corresponding to the lower plate. A sensible heat exchanger and a first latent heat exchanger lower plate having a space penetrated therein corresponding to the upper plate on the upper part of the sensible heat exchanger, and a plurality of corrugated waves perpendicular to the first latent heat exchanger lower plate on the upper part of the first latent heat exchanger lower plate. Each of the two waveplates is symmetrically coupled to each other so that a first latent heat wave heat exchanger is formed to form a first latent heat exhaust pipe path through which the exhaust gas can move. The upper and lower portions of the first latent heat wave heat exchanger are respectively provided with exhaust gas. A first latent heat exchanger cover of a plate type having a through-hole formed to correspond to the first latent heat exhaust pipe can be provided, and the first latent heat A first latent heat exchanger side plate is provided on the outer circumferential surface of the corrugated heat exchanger so as to be perpendicular to the first latent heat exchanger bottom plate, and the first latent heat exchanger having a space penetrated therein to correspond to the first latent heat exchanger bottom plate at an upper portion of the first latent heat exchanger side plate. The upper plate is provided, each of which is provided by stacking in multiple stages, the upper one side of the multi-stage is provided with a water inlet for receiving water, the lower one side is provided with a water outlet for discharging water, the multi-stage inside is stacked A first latent heat exchanger and a water circulation hole symmetrically penetrated zigzag so that water passes from the top to the bottom of each stage in a symmetrical manner, and is provided on an upper portion of the first latent heat exchanger upper plate. A second lower plate having a space penetrated therein is provided to correspond to the upper plate of the first latent heat exchanger, and an upper portion of the second lower plate is provided. A plurality of wave plates each having a corrugated waveform perpendicular to the second lower plate is provided with a second waveform heat exchanger formed with a second exhaust pipe through which the waveforms are symmetrically coupled so that exhaust gas can move between the wave plates, and an upper portion of the second waveform heat exchanger. Each of the lower and lower portions is provided with a flat plate-shaped second heat exchanger cover having a through hole corresponding to the second exhaust pipe passage, and the outer circumferential surface of the second wave heat exchanger is formed on the outside of the outside air outlet and the outside on the other side, respectively. A second side plate is formed through the outside air inlet through which air is introduced, and a plurality of through holes are formed in the outside air inlet, and the upper plate of the plate type for distributing and supplying the exhaust gas is provided. A second latent heat exchanger having a second upper plate formed therein with a space penetrated therein, and provided on an upper portion of the second latent heat exchanger; The upper portion of the separator separation plate having a space penetrated inside to correspond to the second upper plate, the upper portion of the separation plate is formed in a plate-like zigzag form a plurality of separation separators each spaced apart The upper end of each of the separators is provided with a block formed bent downward, the separator and the outer peripheral surface of the separator is provided with a separator side plate, the upper portion of the separator side plate corresponding to the bottom plate of the separator. A separator having a separator top plate having a penetrating space formed thereon, and an upper portion of the separator separated from an upper portion of the separator plate having an outlet bottom plate having a space penetrated therein to correspond to the separator separator upper plate, The upper part and the lower part are opened at the upper part of the outlet lower plate, and the outer peripheral surface is narrowed upwards. The outlet side plate is provided, and one side of the outlet side plate is provided with a discharge part through which a through inlet is formed, and is connected to an air inlet port of the sensible heat exchanger and an outside air outlet of the second latent heat exchanger to sensible heat of the second latent heat exchanger. And a circulating duct supplied to the exchanger, and a mixing duct connected to the air outlet and the inlet of the outlet of the sensible heat exchanger to supply external air discharged through the air outlet to the outlet through the inlet. It provides a reduction in white smoke generation and waste heat recovery and water recovery using the same.

The reduction in white smoke generation and waste heat recovery and water recovery apparatus using the same according to the present invention are performed by using a simple structure to recover the waste heat without directly discharging the high-temperature exhaust gas used in the facility into the atmosphere, and to collect energy as a heat source such as heating. Energy consumption can be reduced by reuse, and condensation of water contained in the exhaust gas can be condensed and used again to reduce the consumption of water used as cooling water.

In addition, by condensing the moisture contained in the exhaust gas in a large amount for the generation of white smoke in the winter, there is an advantage that it is easy to reduce the generation of white smoke.

1 is a perspective view of the reduction of white smoke generation and waste heat recovery and water recovery apparatus using the same according to the present invention,
Figure 2 is a perspective view showing a cross-section of the white smoke generation reduction and waste heat recovery and water recovery device using the same according to the present invention,
Figure 3 is a front sectional view showing the flow of gas and fluid in the reduction of white smoke generation and waste heat recovery and water recovery apparatus using the same according to the present invention,
Figure 4 is an exploded perspective view of the reduction of white smoke generation and waste heat recovery and water recovery device using the same,
5 is a perspective view of the water recovery unit according to the present invention;
6 is an exploded perspective view of the water recovery unit according to the present invention;
7 is a perspective view of the sensible heat exchanger according to the present invention;
8 is an exploded perspective view of a sensible heat exchanger according to the present invention;
9 is a perspective view showing a cross section of the sensible heat exchanger according to the present invention;
10 is a perspective view showing a state in which the first latent heat exchanger is stacked in multiple stages according to the present invention;
11 is an exploded perspective view showing a state in which the first latent heat exchanger is disassembled according to the present invention;
12 is a cross-sectional perspective view showing a state in which the first latent heat exchanger is stacked in multiple stages according to the present invention;
13 is an exploded perspective view showing a state in which the first latent heat exchanger is disassembled according to the present invention;
14 is a perspective view of a second latent heat exchanger according to the present invention;
15 is an exploded perspective view showing an exploded view of a second latent heat exchanger according to the present invention;
16 is a cross-sectional perspective view showing a cross section of a second latent heat exchanger according to the present invention;
17 is a perspective view of the separator according to the present invention,
18 is an exploded perspective view showing an exploded view of the separator according to the present invention,
19 is a front sectional view showing a cross section of the separator according to the present invention;
20 is a partial cross-sectional perspective view showing the inside of the circulation duct according to the present invention;
21 is a perspective view showing the moisturizing of the dispersion plate according to another embodiment of the present invention;
Figure 22 is a cross-sectional view showing the moisture provided with water discharge portion according to another embodiment of the present invention,
23 is a perspective view of a water discharge unit according to another embodiment of the present invention;
24 is an exploded perspective view of the water discharge unit according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to Figures 1 to 24, the reduction of white smoke generation and waste heat recovery and water recovery apparatus using the same according to the present invention is an exhaust gas input pipe (4) for supplying the exhaust gas containing water vapor, and the exhaust gas input pipe ( 4) a water recovery unit 10 connected to the discharge gas and a sensible heat exchanger 20 provided above the water recovery unit 10, and a first latent heat provided above the sensible heat exchanger 20; An exchanger 30, a second latent heat exchanger 40 provided on the first latent heat exchanger 30, a separator separator 50 provided on an upper portion of the second latent heat exchanger 40, and the brackish water. A circulation duct 70 connected to an outlet 60 provided at the top of the separator 50, an air inlet 25 of the sensible heat exchanger 20, and an external air outlet 45 of the second latent heat exchanger 40. And, consisting of the mixing duct 80 is provided to be connected to the inlet hole 63 of the air outlet 26 and the outlet 60 of the sensible heat exchanger 20 The.

Exhaust gas introduction pipe 4 for supplying the exhaust gas containing the steam is provided.

At this time, the exhaust gas input pipe (4) is to supply a high-temperature and humid exhaust gas of about 70 ~ 80 ℃ generated in a facility such as an industrial boiler.

Connected to the discharge gas inlet pipe 4 receives the discharge gas through the discharge gas inlet 11 formed on one side, the upper portion of the water recovery upper plate of the flat water recovery hole 12 is formed therein The water collection | recovery part 10 which has 13 is provided.

In addition, the water recovery unit 10 is provided with a water recovery pipe 15 for discharging the water introduced from the upper side on the lower side, the water recovery hole 12 is formed with a plurality of through-holes to distribute and supply the exhaust gas A flat plate bottom portion plate 14 is provided.

At this time, the water discharged through the water recovery pipe 15 is the sensible heat to be described later as the hot and humid exhaust gas supplied through the exhaust gas inlet pipe 4 rises upward through the through hole of the lower plate 14 Water flows through the exchanger 20, the first latent heat exchanger 30 and the second latent heat exchanger 40, and the water generated as the exhaust gas is condensed in the water separator 50 flows down to the water The water collected in the recovery section 10, and the water collected in the water recovery section 10 may be discharged through the water recovery pipe 15, or may be collected and recycled without discarding the water.

In addition, the lower partial plate 14 is provided so that the discharge gas supplied through the exhaust gas inlet pipe 4 is evenly distributed and rises, the shape of the lower partial plate 14 is dispersed in FIG. As in the plate 91, the plate is formed in an uneven shape to form a plurality of through-holes in the upper part of the uneven type so that the exhaust gas is evenly distributed to the upper part, and the water flowing from the upper part in the lower part of the uneven type Collected and discharged through the open both sides may be used to form the water can be collected in the water collection unit 10 formed in the lower portion.

On the other hand, the dispersion plate 91 is provided in the lower portion of the first latent heat exchanger 30 and the water separator 50 as shown in Figure 22 to 24, respectively, is formed of a rectangular tube formed through the inner side to be opened to the upper and lower parts, In one side, a plurality of through-holes are formed to correspond to the uneven portion of the distribution plate 91 so that water collected in the uneven portion of the distribution plate 91 may be discharged. Water connected to the discharged through the through-hole is collected and introduced, the other side is connected to the water recovery pipe 15, the water formed in a tubular shape so that the water introduced through one side can be discharged to the water recovery pipe 15 connected to the other side The discharge pipe 92 may be used to be seated inside the water discharge unit 90, respectively.

At this time, the water discharge unit 90 is to allow the exhaust gas supplied from the lower portion is evenly distributed to the upper portion by the distribution plate 91 seated inside each of the first latent heat exchanger (30), the first 2The water generated by the exhaust gas condensed by the heat exchange of the exhaust gas in the latent heat exchanger 40 and the water separator 50 is discharged directly to the water recovery pipe 15 connected to the water discharge pipe 92 so that the water may be exchanged through the exhaust gas. Is excessively generated to prevent water from flowing back into the discharge gas inlet pipe 4 by generating more water than the amount of water that can be accommodated in the water recovery unit 10. 30) and the lower portion of the water separator 50 are preferably used, but preferably used according to the capacity of the water recovery unit 10 to recover the water.

It is provided on the upper portion of the water recovery portion 10, the upper portion of the water recovery portion upper plate 13 is provided with a plate-type lower plate 21 having a space penetrated inside to correspond to the water recovery portion upper plate (13) In the upper part of the lower plate 21, a plurality of wave plates 6 having a corrugation perpendicular to the lower plate 21 with a thickness of 1 mm to 4 mm are symmetrically coupled to each other so that the exhaust gas moves between the wave plates 6. Corrugated heat exchanger (23) having an exhaust pipe (22) formed therein is provided, and the upper and lower portions of the corrugated heat exchanger (23) have a flat plate formed with a through hole corresponding to the exhaust pipe (22) so that exhaust gas can move, respectively. The heat exchange port cover 24 is provided, and the outer circumferential surface of the corrugated heat exchange port 23 is provided with side plates 27 through which air inlets 25 and air discharge holes 26 are formed. In the upper portion of the upper plate 28 is formed with a space penetrated inside to correspond to the lower plate 21 The heat exchanger 20 is provided.

At this time, the wave plate 6 is formed as a waveform to increase the heat transfer time to increase the time the air stays without turbulence when the air passes between the wave plate 6, the circumferential edge is connected to a plurality of pipes The corrugated heat exchanger (23) consisting of the plurality of wave plates (6) is formed in the upper and lower portions of the corrugated heat exchanger (23) as compared with the heat exchanger filling the upper and lower pipes. It will receive less and does not need to increase the capacity of the fan installed in the existing chimney.

On the other hand, the 70 ~ 80 ℃ exhaust gas supplied to the water recovery unit 10 is dispersed of the water recovery hole 12 penetrated inside the water recovery upper plate 13 formed on the water recovery unit 10 Exhaust gas is evenly distributed through the plate 14 so that the exhaust gas is supplied inside the exhaust pipe passage 22 of the corrugated heat exchange port 23 formed inside the sensible heat exchanger 20 at the upper portion of the water recovery hole 12. 22) The temperature of the exhaust gas supplied inside the outside of the 15 ~ 25 ℃ supplied to the outside of the exhaust pipe passage 22 through the air inlet 25 formed on one side of the circulation duct 70 and the sensible heat exchanger 20 to be described later The heat exchanged by the air causes the exhaust gas temperature inside the exhaust pipe passage 22 to drop to 60 to 70 ° C., and the external air passing outside the exhaust pipe passage 22 is changed by heat exchange with the exhaust gas inside the exhaust pipe passage 22. The temperature is raised to 35 ~ 45 ℃ is discharged through the air outlet 26 formed on the other side of the sensible heat exchanger (20).

The upper part of the sensible heat exchanger 20 is provided with a first latent heat exchanger lower plate 31 having a space penetrated therein so as to correspond to the upper plate 28, and the first latent heat exchanger lower plate 31 is provided on the upper part of the first latent heat exchanger lower plate 31. A first latent heat waveform having a first latent heat exhaust pipe 32 in which a plurality of wave plates 6 having a corrugated shape perpendicular to the lower plate 31 are symmetrically coupled to each other so that exhaust gas can move between the wave plates 6. The heat exchange port 33 is provided, and the first latent heat of flat type having a through hole corresponding to the first latent heat exhaust pipe passage 32 so that the exhaust gas moves to the upper and lower portions of the first latent heat wave heat exchanger 33, respectively. The heat exchange port cover 34 is provided, and the first latent heat exchanger side plate 35 is provided on the outer circumferential surface of the first latent heat exchanger heat exchanger 33 so as to be perpendicular to the first latent heat exchanger lower plate 31. A space penetrated inside the side plate 35 to correspond to the first latent heat exchanger lower plate 31. The formed first latent heat exchanger upper plate 36 is provided, each of which is provided in a multi-stage stack, and a water inlet 37 for supplying water is provided on one side of the upper portion, which is stacked in multiple stages, and a water outlet for discharging water on the lower one side. A first latent heat exchanger 30 having a water circulation hole 39 symmetrically formed in one upper portion and the other lower portion in a zigzag manner so that water passes from the upper side to the lower side in each of the stacked multiple stages. ) Is provided.

At this time, the exhaust gas passing through the exhaust pipe passage 22 of the sensible heat exchanger 20 has a temperature of 60 ~ 70 ℃ is formed in the first latent heat exchanger (30) stacked in multiple stages on the top of the exhaust pipe passage (22) The first latent heat exhaust pipe (32) of the first latent heat wave heat exchanger (33) is respectively supplied to the inside of the first latent heat exhaust pipe (32), the temperature of the exhaust gas supplied to the first latent heat exchanger (30) in multiple stages Water is supplied through the water inlet 37 from the stacked upper one side, and the supplied water is zigzag one side so that the water passes from the top to the bottom every multi-stage stacked in the multi-stage first latent heat exchanger 30. Water is passed from the top to the bottom along the water circulation hole 39 symmetrically formed in the upper portion and the other lower portion, the first latent heat exhaust pipe discharged to the water outlet 38 provided on the lower side of the first latent heat exchanger (30) Heat is exchanged due to the water supplied outside the furnace 32 to the first latent heat exhaust pipe. The exhaust gas temperature inside (32) drops to 40-50 占 폚.

In addition, in the first latent heat exchanger 30, the first condensation of the exhaust gas is started while the exhaust gas temperature is heat exchanged from 60 to 70 to 40 to 50 ° C. The first latent heat exhaust pipe (32) of the latent heat wave heat exchanger (33) flows downward.

At this time, the dew point temperature of the exhaust gas condensed in the first latent heat exchanger (30) is about 55 ~ 65 ℃, the condensation is continuously generated while the exhaust gas passes through the first latent heat exchanger (30), the exhaust gas is While passing through the latent heat exchanger 30, a large amount of latent heat is generated and condensation of the exhaust gas occurs until the temperature of the exhaust gas reaches 40 to 50 ° C.

In addition, the water generated by the condensation of the exhaust gas in the first latent heat exchanger 30 flows downward through the first latent heat exhaust pipe 32 to further activate the condensation of the exhaust gas that has not yet been condensed. It is possible to recover a larger amount of water, and in this process to remove unfiltered fine dust and odors, and also serves to wash the first latent heat exhaust pipe (32).

The second lower plate 41 is provided on an upper portion of the first latent heat exchanger 30 and has a space penetrated therein to correspond to the first latent heat exchanger upper plate 36. These couplings are provided, and a plurality of wave plates 6 having a wave shape perpendicular to the second lower plate 41 are coupled symmetrically to each other so that the exhaust gas moves between the wave plates 6. The second waveform heat exchange port 43 is provided with a second exhaust pipe path 42 which can be formed, and the second exhaust pipe path 42 so that the exhaust gas can move to the upper and lower portions of the second waveform heat exchange port 43, respectively. The second heat exchange hole cover 44 of the plate-shaped hole is formed to correspond to the, and the outer circumferential surface of the second waveform heat exchange hole 43, the outside air outlet 45 formed on one side and the outside air flows into the other side, respectively A second side plate 47 is formed through which the outside air inlet 46 is formed, and the outside air inlet 46 has a plurality of through holes. Is formed is provided with a flat plate-shaped upper dispersion plate 48 for distributing and supplying the exhaust gas, the second side plate 47 is formed on the upper side of the second lower plate 41 to penetrate the inner space corresponding to the second lower plate 41 A second latent heat exchanger 40 having a top plate 49 is provided.

At this time, the second latent heat exchanger (2) having an exhaust gas passing through the first latent heat exhaust pipe (32) of the first latent heat exchanger (30) and having a temperature of 40 to 50 ° C. is provided on the first latent heat exhaust pipe (32) ( 40 is respectively supplied to the inside of the second exhaust pipe 42 of the second waveform heat exchanger 43 formed therein, and the temperature of the exhaust gas supplied to the inside of the second exhaust pipe 42 is the second latent heat exchanger 40. The exhaust gas temperature inside the second exhaust pipe passage 42 is heat-exchanged due to external air of 0 to 10 ° C. flowing into the outside of the second exhaust pipe passage 42 through the outside air inlet 46 formed through the other side of the second exhaust pipe passage 42. 40 ° C., the outside air heat exchanged with the exhaust gas is supplied to the circulation duct 70 through an outside air outlet 45 formed through one side of the second latent heat exchanger 40 at a temperature of 15 ° C. to 25 ° C., The exhaust gas passing through the second latent heat exchanger 40 is in a state of saturated steam having a temperature of 30 to 40 ° C.

Meanwhile, the circulation duct 70 is connected to the air inlet 25 of the sensible heat exchanger 20 and the external air outlet 45 of the second latent heat exchanger 40 to sensible heat of the second latent heat exchanger 40. It serves to supply to the exchanger (20), the inside of the circulation duct 70 is provided with a flat blower fixing plate 71 of the through hole is formed to install the blower 72 in the through hole of the blower fixing plate 71 It can also be used.

It is provided on the upper part of the second latent heat exchanger 40, the upper portion of the second upper plate 49 is provided with a separator separator lower plate 51 having a space penetrated therein to correspond to the second upper plate 49, Is formed in a plate shape on the top of the separator plate lower plate 51 is provided with a plurality of separation separators 52 having a zigzag shape in the upper direction, respectively, bent downward at the upper end of each of the separation separator 52 A breaker 53 is provided, and the water separator 52 and the outer circumferential surface of the block 53 are provided with a separator side plate 54, and the separator separator lower plate 51 is provided on the top of the separator side plate 54. A separator 50 having a separator upper plate 55 formed therein with a space penetrated therein is provided.

At this time, the exhaust gas passing through the second exhaust pipe (42) of the second latent heat exchanger (40) to a temperature of 20 ~ 30 ℃ in the state of saturated steam is provided on the second exhaust pipe (42) top separator ) Is provided in a plate-shaped inside of the plurality of rider separators 52 having a zig-zag shape in the upper direction and supplied to the blocking port 53 formed bent downward at the upper end of each of the rider separators 52, separating the rider The exhaust gas supplied to the sphere 52 and the shutoff 53 is condensed and separated from the moisture contained in the exhaust gas and flows to the lower portion, and further activates the condensation of the exhaust gas that has not yet condensed as it flows to the lower portion. It will condense positive exhaust gases.

The upper portion of the separator 50 is provided, the upper portion of the separator separator upper plate 55 is provided with a discharge outlet lower plate 61 having a space penetrated inside to correspond to the upper separator 55, the discharge lower plate ( The upper portion and the lower portion of the upper portion 61 is formed to be open, the outer peripheral surface is provided with an outlet side plate 62 narrowing in the upward direction, the one side of the outlet side surface plate 62 is formed with a through inlet hole 63, Inside the inlet hole 63 is provided with a discharge part 60 having a flat plate outlet outlet plate 64 formed with a plurality of through-holes inside, the discharge portion 60 is provided with an air outlet 26 and the discharge portion ( Both sides of the inlet hole 63 of the 60 are connected to each other, and the outside air discharged through the air outlet 26 is formed through the plurality of through holes formed in the outlet distribution plate 64 provided inside the inlet hole 63. The mixing duct 80 is provided to evenly distribute the supplied to the discharge unit (60).

At this time, the exhaust gas passing through the water separator 52 and the blocking port 52 of the water separator 50 is condensed by the water contained in the exhaust gas is separated from the discharge portion provided in the upper portion of the separator 50 ( 60 to 30, the exhaust gas of 30 ~ 40 ℃ supplied to the discharge unit 60 and the air outlet 26 of the inlet hole 63 and the sensible heat exchanger 20 provided on one side of the discharge unit 60 and The temperature supplied through the connected mixing duct 80 is mixed with external air having a temperature of 35 ~ 45 ℃ is discharged to the outside.

At this time, the exhaust gas discharged through the discharge unit 60 is less than 50% humidity, low humidity contained in the exhaust gas is not generated white smoke phenomenon.

Reduction of white smoke generation and waste heat recovery and water recovery apparatus using the same according to the present invention made as described above does not discharge the high-temperature exhaust gas used in the facility as it is, even with a simple structure, and recovers waste heat to heat energy such as heating. It is possible to reduce the energy wasted by reusing, by condensing the moisture contained in the exhaust gas in large quantities to recover and use again has the advantage of reducing the consumption of water used as cooling water.

In addition, there is an advantage that the white smoke is reduced by condensing and recovering the moisture contained in the exhaust gas in a large amount for the generation of white smoke in the winter, there is an advantage that the fine dust and odor contained in the exhaust gas is removed.

2: white smoke reduction device 4: exhaust gas input pipe
6: Papan 10: Water recovery part
11: exhaust gas inlet 12: water recovery
13: Water recovery upper plate 14: Lower part plate
15: water recovery pipe 20: sensible heat exchanger
22: exhaust pipe path 23: corrugated heat exchanger
25: air inlet 26: air outlet
30: first latent heat exchanger 32: first latent heat exhaust pipe
33: first latent heat waveform heat exchange port 37: water inlet
38: water outlet 39: water circulation hole
40: second latent heat exchanger 42: to the second exhaust pipe
43: second waveform heat exchange port 45: outside air outlet
46: outside air inlet 48: upper dispersion plate
50: separator separator 60: discharge part
70: circulation duct 80: mixed duct

Claims (5)

An exhaust gas inlet pipe 4 for supplying exhaust gas including water vapor;
Connected to the discharge gas inlet pipe 4 receives the discharge gas through the discharge gas inlet 11 formed on one side, the upper portion of the water recovery upper plate of the flat water recovery hole 12 is formed therein A water recovery portion 10 having a water discharge portion 13;
The lower plate 21 is provided on the upper portion of the water recovery portion 10, the lower plate 21 having a space penetrated inside to correspond to the water recovery portion upper plate 13, the lower plate ( Corrugated heat exchange in which a plurality of wave plates 6 corrugated perpendicular to the lower plate 21 are coupled symmetrically to the upper portion of the lower plate 21 to form an exhaust pipe passage 22 through which the exhaust gas can move between the wave plates 6. A sphere 23 is provided, and the upper and lower portions of the corrugated heat exchanger 23 are provided with a flat heat exchanger cover 24 having a through hole corresponding to the exhaust pipe passage 22 so that the exhaust gas can move. The outer circumferential surface of the corrugated heat exchanger 23 is provided with side plates 27 through which air inlets 25 and air outlets 26 are formed, and the upper side of the side plates 27 corresponds to the lower plate 21. A sensible heat exchanger (20) having a top plate (28) formed therein with a space therethrough;
The upper part of the sensible heat exchanger 20 is provided with a first latent heat exchanger lower plate 31 having a space penetrated therein so as to correspond to the upper plate 28, and the first latent heat exchanger lower plate 31 is provided on the upper part of the first latent heat exchanger lower plate 31. A first latent heat waveform having a first latent heat exhaust pipe 32 in which a plurality of wave plates 6 having a corrugated shape perpendicular to the lower plate 31 are symmetrically coupled to each other so that exhaust gas can move between the wave plates 6. The heat exchange port 33 is provided, and the first latent heat of flat type having a through hole corresponding to the first latent heat exhaust pipe passage 32 so that the exhaust gas moves to the upper and lower portions of the first latent heat wave heat exchanger 33, respectively. The heat exchange port cover 34 is provided, and the first latent heat exchanger side plate 35 is provided on the outer circumferential surface of the first latent heat exchanger heat exchanger 33 so as to be perpendicular to the first latent heat exchanger lower plate 31. A space penetrated inside the side plate 35 to correspond to the first latent heat exchanger lower plate 31. The formed first latent heat exchanger upper plate 36 is provided, each of which is provided in a multi-stage stack, and a water inlet 37 for supplying water is provided on one side of the upper portion, which is stacked in multiple stages, and a water outlet for discharging water on the lower one side. A first latent heat exchanger 30 having a water circulation hole 39 symmetrically formed in one upper portion and the other lower portion in a zigzag manner so that water passes from the upper side to the lower side in each of the stacked multiple stages. );
The second lower plate 41 is provided on an upper portion of the first latent heat exchanger 30 and has a space penetrated therein to correspond to the first latent heat exchanger upper plate 36. These couplings are provided, and a plurality of wave plates 6 having a wave shape perpendicular to the second lower plate 41 are coupled symmetrically to each other so that the exhaust gas moves between the wave plates 6. The second waveform heat exchange port 43 is provided with a second exhaust pipe path 42 which can be formed, and the second exhaust pipe path 42 so that the exhaust gas can move to the upper and lower portions of the second waveform heat exchange port 43, respectively. The second heat exchange hole cover 44 of the plate-shaped hole is formed to correspond to the, and the outer circumferential surface of the second waveform heat exchange hole 43, the outside air outlet 45 formed on one side and the outside air flows into the other side, respectively A second side plate 47 is formed through which the outside air inlet 46 is formed, and the outside air inlet 46 has a plurality of through holes. Is formed is provided with a flat plate-shaped upper dispersion plate 48 for distributing and supplying the exhaust gas, the second side plate 47 is formed on the upper side of the second lower plate 41 to penetrate the inner space corresponding to the second lower plate 41 A second latent heat exchanger 40 having a top plate 49;
It is provided on the upper part of the second latent heat exchanger 40, the upper portion of the second upper plate 49 is provided with a separator separator lower plate 51 having a space penetrated therein to correspond to the second upper plate 49, Is formed in a plate shape on the top of the separator plate lower plate 51 is provided with a plurality of separation separators 52 having a zigzag shape in the upper direction, respectively, bent downward at the upper end of each of the separation separator 52 A breaker 53 is provided, and the water separator 52 and the outer circumferential surface of the block 53 are provided with a separator side plate 54, and the separator separator lower plate 51 is provided on the top of the separator side plate 54. A separator 50 having a separator separator upper plate 55 formed therein with a space penetrating therein;
The upper portion of the separator 50 is provided, the upper portion of the separator separator upper plate 55 is provided with a discharge outlet lower plate 61 having a space penetrated inside to correspond to the upper separator 55, the discharge lower plate ( The upper part and the lower part of the upper part 61 are formed to be open, and an outlet side plate 62 having an outer circumferential surface narrowing in an upward direction is provided, and one side of the outlet side plate 62 has a discharged inlet hole 63 formed therein. Part 60;
The air inlet 25 of the sensible heat exchanger 20 and the external air outlet 45 of the second latent heat exchanger 40 are connected to supply the external air of the second latent heat exchanger 40 to the sensible heat exchanger 20. Duct 70;
It is provided to be connected to the air outlet 26 and the inlet hole 63 of the outlet 60 of the sensible heat exchanger 20 through the inlet hole 63 of the external air discharged through the air outlet 26 ( Reduction of white smoke generation and waste heat recovery and water recovery device using the same, characterized in that it comprises a mixed duct (80) to be supplied to. The method of claim 1,
Reduction of white smoke generation and waste heat recovery and water recovery device using the same, characterized in that the thickness of the wave plate (6) is formed of 1mm ~ 4mm. The method of claim 1,
Reduction of white smoke generation and waste heat recovery and water recovery apparatus using the same, characterized in that the water recovery pipe 15 is formed on the lower side of the water recovery unit 10 to discharge the introduced water. The method of claim 1,
Reduced white smoke generation, characterized in that the inside of the circulation duct 70 is provided with a flat blower fixing plate 71 having a through hole is formed, the blower 72 is provided in the through hole of the blower fixing plate 71 and Waste heat recovery and water recovery device using the same. The method of claim 1,
The water recovery hole 12 and the inlet hole 63 is formed with a plurality of through-holes are provided with a flat plate-type lower plate 14 and the discharge distribution plate 64 to distribute the exhaust gas Reduction of white smoke and waste heat recovery and water recovery system using the same.

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