RU2809298C1 - Exhaust heat recovery and white smoke reduction device with precooler - Google Patents

Abstract

FIELD: heat recovery devices; white smoke reduction devices.

SUBSTANCE: invention relates to devices for exhaust gas heat recovery and white smoke reduction with a pre-cooler. A moisture absorption unit, which, by receiving the first exhaust gas containing high-temperature water vapor through the exhaust gas supply pipe, absorbs moisture and heat from the first exhaust gas through the water-absorbing liquid, discharges the second exhaust gas in a state in which the first exhaust gas is dried at a low temperature using the exhaust gas outlet pipe. In the storage unit, the water-absorbing liquid contacting with the first exhaust gas is discharged from the moisture absorption unit and stored. A pre-cooler is provided on the exhaust gas supply pipe to cool the heat of the first exhaust gas with fresh water supplied from outside. The heat exchange unit is a pipe for supplying water-absorbing liquid from the storage unit to the water-absorbing unit and a pipe for supplying cold water to the other side. Cold water absorbs the heat of the water absorber. A hot water discharge pipe is connected to the heat exchange unit to absorb heat and discharge the generated hot water. On one side of the regeneration unit, a water-absorbing liquid regeneration pipe is connected, into which the water-absorbing liquid flows from the accumulation unit, and on the other side, a steam pipe is connected through which high-temperature steam is supplied and heated by steam to produce water absorber, and which is connected to the separation outlet pipe through which the water-absorbing liquid and steam separated from the water-absorbing liquid are discharged. A separation outlet pipe is connected to the gas and liquid separation unit, and a steam exhaust pipe for releasing water vapor and a water-absorbing liquid recovery pipe for recovering moisture separated from water vapor are connected to the accumulation unit. The heat exchange unit includes a first heat exchanger and a second heat exchanger, one side of the first heat exchanger is connected to a water-absorbing liquid supply pipe, and the other side is connected to a cold water supply pipe and a hot water exhaust pipe. One side of the second heat exchanger is connected to a hot water exhaust pipe, and the other side may be connected to a steam exhaust pipe of the gas-liquid separator. The inlet and outlet pipes of the incoming water precooler are connected to the precooler. A cold water supply pipe connected to the first heat exchanger is connected to a precooler supply pipe and a precooler discharge pipe.

EFFECT: increasing the efficiency of heat recovery.

14 cl, 5 dwg

Description

Technical field

The present invention is an exhaust gas heat recovery and white smoke reduction apparatus equipped with a precooler, and more specifically, it is an apparatus having a precooler for absorbing exhaust gas heat at a front end of a moisture absorption unit.

Prior Art

Typically, since air pollutant-emitting facilities such as incinerators, smelters, boilers, wet desulfurization plants, etc., during operation, emit high-temperature exhaust gases containing high concentrations of pollutants into the atmosphere to remove the pollutants contained in these exhaust gases, an absorption column was mainly installed and used to remove harmful substances by spraying an aqueous solution (wet dust collection unit).

Since such wet dust collectors spray water onto the high-temperature exhaust gases being emitted, the exhaust gas exits into the air through the chimney in a high-temperature, high-humidity (saturated) state. Then, since the moisture contained in the exhaust gas includes pollutants and saturated moisture that cannot be removed by the wet dust collector, the exhaust gas containing saturated moisture when leaving the chimney is immediately cooled by the cold temperature of the outside atmosphere, the saturated moisture in the exhaust gases, which condenses and has an increased specific gravity, is converted into droplets of water and intensively falls near the chimney, polluting the surroundings of the chimney.

In addition, water droplets, which are droplets with a relatively low specific gravity, do not spread, and forming white smoke in the form of a belt of water vapor at a certain distance from the chimney, falling and falling droplets corrode the surrounding structures and cause complaints from residents.

Traditionally, in wet removal of harmful gases generated at pollutant emission sites, in order to prevent the formation of white smoke through the chimney, the relative humidity of the exhaust gases is reduced by mixing high-temperature air from outside, or the exhaust gases are directly heated by installing a burner on the chimney and thus removing moisture in the exhaust gases The former has the problem of very high installation costs, while the latter has the problem of high maintenance costs due to fuel consumption.

For example, among the patent documents to solve this problem, there are a number of patent documents, including Patent Documents 1 and 2. However, these patented technologies, as described above, not only include complex devices (wet dust collectors) etc., but also do not solve the white smoke problem sufficiently. In addition, since the waste heat of the exhaust gases is exchanged at normal heat exchange rates, it tends to be inefficient in terms of energy use.

On the other hand, exhaust gases emitted from source facilities such as incinerators contain saturated moisture at high temperatures.

By examining the physical characteristics of wet exhaust gases using the already known wet air diagram (psychometric diagram), a t-x diagram (t: temperature, x: absolute humidity) with dry bulb temperature and absolute humidity as coordinates, ranging from 0 to 60 °C The growth curve of absolute humidity forms a flat curve (gradual increase), then in the range from 60 to 70°C, absolute humidity increases along a steep upward curve, and in the temperature range of 70°C and above, absolute humidity is almost vertical even with a small temperature difference.

Therefore, if the temperature and humidity of exhaust gases emitted from exhaust gas sources such as incinerators and boilers, in the temperature range above 60°C, can be reduced to an economically feasible temperature and humidity (exhaust temperature up to 60°C, absolute humidity up to 40°C), when released into the atmosphere in a supercooled state, most of the white smoke generated from the exhaust gases can be reduced.

Disclosure of the Invention

Technical problem

The purpose of this invention is to provide an exhaust heat recovery and white smoke reduction device with a precooler. More specifically, an object of the present invention is to provide an exhaust heat recovery and white smoke reduction device with a pre-cooler, which has a pre-cooler for absorbing exhaust gas heat at a front end of a moisture absorption unit.

Technical solution

An exhaust heat recovery and white smoke reduction device having a pre-cooler according to an example of the present invention is composed of a moisture absorption unit that, taking the first exhaust gas containing high-temperature water vapor through the exhaust gas supply pipe, absorbs moisture and heat from the first exhaust gas through the desiccant liquid, discharges the second exhaust gas in a state in which the first exhaust gas is dried at a low temperature through the exhaust gas exhaust pipe; a storage unit in which desiccant liquid in contact with the first exhaust gas is discharged from the desiccant unit and stored; and a pre-cooler provided on the exhaust gas supply pipe for cooling the heat of the first exhaust gas with supply water supplied from outside.

In the precooler, the first exhaust gas may be cooled from a first temperature above 100°C to a second temperature between the first temperature and 100°C.

In addition, to recover heat from the desiccant liquid, a heat exchange unit can be additionally included, which is a connected desiccant liquid supply pipe on one side, through which the desiccant liquid is supplied from the storage unit to the moisture absorption unit, and a cold water supply pipe, through which the cold water is supplied to the other side and the cold water absorbs the heat of the dehumidifier, and to which a hot water discharge pipe is connected to absorb the heat and discharge the generated hot water.

The pre-cooler is connected to the cold water supply pipe or hot water discharge pipe so that cold or hot water is supplied as inflow, and the incoming water absorbs the heat of the first exhaust gas in the pre-cooler and is supplied to the cold water supply or hot water discharge pipe.

A precooler inlet pipe through which incoming water is supplied and a precooler outlet pipe through which incoming water is discharged are connected to the precooler, and the precooler inlet pipe is connected to a cold water supply pipe or a hot water outlet pipe. To control the supply of incoming water, a pre-cooler supply valve is turned on, with the pre-cooler discharge pipe connected to the pipe to which the pre-cooler supply pipe is connected, between a cold water supply pipe or a hot water discharge pipe, and includes a pre-cooler discharge valve to control the release of the incoming water. water; a precooler bypass valve operating opposite the precooler supply valve and a precooler outlet valve may be provided between a portion where a precooler supply pipe is connected and a portion where a precooler discharge pipe is connected to a cold water supply pipe or a hot water discharge pipe.

For example, each of the precooler supply pipe and the precooler outlet pipe may be connected to a cold water supply pipe and a hot water outlet pipe, and when cold water is supplied to the precooler, the precooler supply valve and the precooler outlet valve are connected to the hot water outlet pipe , are closed, the pre-cooler bypass valve connected to the hot water drain pipe is turned on, and hot water is supplied to the pre-cooler, the pre-cooler supply valve and the pre-cooler discharge valve connected to the cold water supply pipe are closed, the pre-cooler bypass valve connected to the supply pipe cold water can be turned on.

An emergency control unit may be provided at the end of the exhaust gas supply pipe and at the end of the exhaust gas exhaust pipe to discharge the first exhaust gas outside without passing through the moisture absorption unit.

The emergency control unit may include an exhaust gas supply valve connected to the exhaust gas supply pipe, an exhaust gas supply valve connected to the exhaust gas discharge pipe, and an exhaust gas supply valve and an exhaust gas release valve, and operating opposite the exhaust gas supply valve and the exhaust valve. exhaust gas, and a moisture absorption device bypass valve for controlling the discharge of the first exhaust gas to the outside without passing through the moisture absorption device.

Additionally, a fan may be provided located on the exhaust gas exhaust pipe and increases the discharge speed of the second exhaust gas discharged from the moisture absorption unit.

The storage unit includes a plurality of baffles provided within the storage unit to direct the flow of desiccant liquid to the desiccant liquid supply pipe, and a filter installed between the plurality of baffles for filtering foreign matter from the desiccant liquid.

In addition, a metering unit may be additionally included, one end of which is connected to the accumulation unit and replenishes the desiccant liquid into the accumulation unit in accordance with at least one of the following parameters: level, specific gravity, concentration, acidity, purity, viscosity and temperature of the desiccant liquid contained in the accumulation block.

In addition, a regeneration unit may also be included, in which, on one side, a desiccant liquid regeneration pipe is connected, into which the desiccant liquid flows from the accumulation unit, and on the other side, a steam pipe is connected through which high-temperature steam is supplied and heated by the steam to obtain a desiccant and which connected to a separation outlet pipe through which the desiccant liquid and steam separated from the desiccant liquid are discharged; and a gas-liquid separation unit, to which a separation outlet pipe is connected on one side, and a steam removal pipe for releasing water vapor and a desiccant liquid recovery pipe for recovering moisture separated from the water vapor are connected to the accumulation unit.

The heat exchange unit includes a first heat exchanger and a second heat exchanger, one side of the first heat exchanger is connected to a desiccant liquid supply pipe, and the other side is connected to a cold water supply pipe and a hot water exhaust pipe, and one side of the second heat exchanger is connected to a hot water exhaust pipe, and the other side can be connected to the vapor exhaust pipe of the gas-liquid separator.

A cold water supply pipe connected to the first heat exchanger may be connected to a precooler supply pipe and a precooler discharge pipe, and a hot water discharge pipe connected to the second heat exchanger may be connected to a precooler supply pipe and a precooler discharge pipe.

A heater connected to the exhaust gas outlet pipe on one side through which the second exhaust gas is introduced to heat and discharge the second exhaust gas may be further turned on.

The heater supply pipe and the heater outlet pipe can be connected to the steam exhaust pipe, and the heater outlet pipe can be connected to the hot water outlet pipe.

Included are a heater supply valve provided on the heater supply pipe for controlling the supply of steam, a heater outlet valve provided on the heater outlet pipe for releasing condensed hot water, a portion connected to the heater supply pipe on the steam exhaust pipe, and a second heat exchanger, and a valve supplying steam to the second heat exchanger, wherein the heater supply valve and the heater outlet valve may operate opposite the second heat exchanger supply valve.

When the heater supply valve and the heater outlet valve are open or closed, the second heat exchanger supply valve may be closed or open.

Invention effect

According to the example of the present invention, by providing a pre-cooler for absorbing exhaust gas heat at the front end of the dehumidification unit, the waste heat from the exhaust gas can be more effectively recovered, and by achieving the optimum temperature of the exhaust gas supplied to the dehumidification portion, the moisture absorption unit can sufficiently absorb moisture and latent heat from the exhaust gases, thereby further increasing the efficiency of latent heat recovery and reducing white smoke.

Brief description of drawings

Rice. 1 is a diagram for explaining an exhaust heat recovery and white smoke reduction apparatus with a pre-cooler according to the first embodiment of the present invention.

Rice. 2 is a diagram explaining the change in exhaust gas temperature by the exhaust heat recovery and white smoke reduction device with pre-cooler shown in Fig. 1.

Rice. 3 is a diagram for explaining the first modified example in which the pre-cooler is connected to the hot water discharge pipe in the first embodiment of the present invention.

Rice. 4 is a diagram for explaining a second modified example in which the pre-cooler is connected to a cold water supply pipe and a hot water discharge pipe in the first embodiment of the present invention.

Rice. 5 is a diagram for explaining an exhaust heat recovery and white smoke reduction apparatus with a pre-cooler according to a second embodiment of the present invention.

Embodiments of the Invention

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that the addition of a detailed description of technology or configuration already known in the art would make it difficult to understand the essence of the present invention, some of them will be omitted from the detailed description. Also, the terms used in this description are terms used to properly express embodiments of the present invention, they may vary depending on persons or customs associated with the field. Therefore, definitions of these terms must be made based on the contents of this entire specification.

The terminology used herein is intended to indicate specific embodiments only and is not intended to limit the present invention. The singular forms used herein also include the plural forms unless language clearly indicates otherwise. The meaning "comprising" as used in the specification defines specific characteristics, areas, integers, steps, operations, elements and/or components; and there may be the presence or addition of other special characteristics, areas, integers, steps, operations, elements, components and/or groups.

The present invention will now be described with reference to the accompanying drawings.

Rice. 1 is a diagram for explaining an exhaust heat recovery and white smoke reduction apparatus with a rear heater according to the first embodiment of the present invention, and Fig. 2 is a diagram explaining the change in exhaust gas temperature by the rear heater exhaust heat recovery and white smoke reduction device shown in Fig. 1.

As shown in Fig. 1, an exhaust heat recovery and white smoke reduction apparatus with a rear heater according to the first embodiment of the present invention, located between the exhaust gas supply source (1) and the chimney (2), by removing moisture and latent heat of the exhaust gas supply and discharging them into the chimney (2), the phenomenon of white smoke of exhaust gases emitted through the chimney (2) is reduced, the heat of the exhaust gases can be absorbed and used as hot water.

According to the first embodiment of the present invention, the rear heater exhaust heat recovery and white smoke reduction apparatus, by providing a pre-cooler (30) for absorbing exhaust gas heat at the front end of the dehumidification unit (10), the waste heat from the exhaust gas can be more effectively recovered , and by achieving the optimal temperature of the exhaust gas supplied to the moisture absorption unit (10), the moisture absorption unit (10) can sufficiently absorb moisture and latent heat from the exhaust gas, thereby further improving the efficiency of latent heat recovery and reducing white smoke .

As shown in Fig. 1, an exhaust heat recovery and white smoke reduction apparatus with a rear heater according to the first embodiment of the present invention includes a moisture absorption unit (10), a storage unit (20) and a pre-cooler (30). Additionally, a heat exchange unit (40), an emergency control unit (50), a fan (60), a dosing unit (70), a regeneration unit (80) and a gas-liquid separation unit (90) may be included.

The moisture absorption unit (10) can perform the function of recovering moisture and latent heat from the exhaust gas, one side being connected to the exhaust gas supply source (1) through the exhaust gas supply pipe (P1), and the other side being connected to the chimney pipe (2 ) through the exhaust pipe (P2). The first exhaust gas before moisture and latent heat recovery can be placed in the exhaust gas supply source (1).

The moisture absorption unit (10) receives the first exhaust gas containing high temperature water vapor through the exhaust gas supply pipe (P1) connected to the bottom of the moisture absorption unit (10), and absorbs latent heat from the first exhaust gas through the desiccant liquid, the first exhaust the gas is converted into a second exhaust gas dried at a low temperature, and the second exhaust gas can be discharged through an exhaust gas discharge pipe (P2) connected to the upper end of the moisture absorption unit (10).

Here, the first exhaust gas is supplied from the exhaust gas supply source (1) to the moisture absorption unit (10) through the exhaust gas supply pipe (P1), and may be in a state containing a large amount of moisture at a temperature of 60°C to 200°C. Although there is a difference depending on the season, the atmospheric temperature, the initial process and the type of the first exhaust gas, at least in summer the first exhaust gas can have a high temperature above 100 °C and contain a large amount of moisture.

The second exhaust gas is the exhaust gas released after moisture and latent heat are recovered by the desiccant liquid in the moisture absorption unit (10), and may have a temperature up to 100° C. lower than the temperature of the first exhaust gas and be in a dry state.

The desiccant liquid is a solution containing hygroscopic salts and may be a material that absorbs moisture and latent heat from the first exhaust gas, causing a heat recovery chemical reaction upon contact with the first exhaust gas. Such a desiccant liquid is recovered by cooling and condensing the moisture contained in the first exhaust gas, reduces the absolute humidity of the first exhaust gas into a low-temperature dry second exhaust gas, and can reduce the white smoke phenomenon of the exhaust gas emitted into the atmosphere through the chimney (2).

In one embodiment, the desiccant liquid is a liquid from the group of calcium nitrate, ammonium nitrate, ammonium sulfate, barium nitrate, barium perchlorate, potassium formate, sodium chlorate, sodium nitrate, potassium nitrate, sodium chloride and calcium chloride, where one or more may be included selected materials, and the absorbent concentration can range from 40 to 80% by weight.

Such a desiccant liquid can absorb the heat and moisture of the first exhaust gas and have high heat and low concentration. The high-heat desiccant liquid can transfer heat to cold water supplied from outside as it circulates through the device, thereby turning cold water into hot water.

In addition, the reduced concentration desiccant liquid can be heated with high pressure steam so that the chemical properties capable of retaining moisture can be restored to a predetermined state.

The desiccant liquid is supplied through the desiccant liquid supply pipes (P4, P5) connected to the upper part of the moisture absorption unit (10), and through the desiccant liquid discharge pipe (P6) connected to the lower part of the moisture absorption unit (10), the desiccant liquid is supplied which has absorbed moisture and heat from the gas, can be released.

To increase the contact area between the desiccant liquid and the first exhaust gas, a spray nozzle for spraying the desiccant liquid in a radial direction may be provided at the upper end of the moisture absorption unit (10).

Accordingly, the first exhaust gas supplied to the lower end of the moisture absorption unit (10) rises in the direction of the arrow inside the moisture absorption unit (10), and the desiccant liquid is sprayed through the injection nozzle and falls in the direction indicated by the arrow. When the desiccant liquid and the first exhaust gas come into contact with each other, the moisture and heat contained in the first exhaust gas can be absorbed by the desiccant liquid.

Accordingly, the first exhaust gas is deprived of moisture and heat and converted into a second low-temperature dry exhaust gas, and moves into the chimney (2) through the exhaust gas outlet pipe (P2) to be discharged into the atmosphere.

Here, the desiccant liquid can circulate through the moisture absorption unit (10), the desiccant liquid discharge pipe (P6), the storage unit (20) and the desiccant liquid supply pipes (P4, P5).

The desiccant liquid discharged through the desiccant liquid discharge pipe (P6) connected to the lower end of the desiccant unit (10) may be stored in the storage unit (20).

The storage unit (20) can be designed as a reservoir in which the moisture-absorbing liquid in contact with the first exhaust gas is removed from the moisture absorption unit (10) and stored. As shown in Fig. 1, the storage unit (20) may include a plurality of baffles (21a, 21b) and a filter (22).

A plurality of baffles (21a, 21b) are provided within the storage unit (20) and may be formed in the form of a plate to direct the desiccant liquid to flow towards the desiccant liquid supply pipes (P4, P5), and the plurality of baffles (21a, 21b) may be included in itself a first partition (21a) extending from top to bottom inside the storage unit (20), and a second partition (21b) extending from bottom to top inside the storage unit (20).

Using the first and second partitions (21a, 21b), the storage unit (20) can be divided into a zone to which the desiccant liquid discharge pipe (P6) is connected, and a zone to which the desiccant liquid supply pipes (P4, P5) are connected.

Accordingly, the desiccant liquid supplied to the storage unit (20) can be directed by the first partition (21a) and the second partition (21b) to move to the area of the desiccant liquid supply pipes (P4, P5).

A filter (22) is positioned horizontally between the first and second baffles (21a, 21b) to filter foreign matter such as dust from the desiccant liquid into which the flow is directed.

For circulating the desiccant liquid, a motor for circulating the desiccant liquid may be provided in the desiccant liquid supply pipes (P4, P5) connected from the storage unit (20) to the moisture absorption unit (10).

In addition, the storage unit (20) may have a desiccant liquid regeneration pipe (P7) connected to the regeneration unit (80), and a motor may be provided for discharging the desiccant liquid into the regeneration unit (80) through the desiccant liquid regeneration pipe (P7).

The storage unit (20) includes a level gauge (24) capable of measuring the stored amount of desiccant liquid, a thermometer (23) capable of measuring the temperature of the stored desiccant liquid and, although not shown, may additionally be provided with at least one sensor capable of measuring acidity, purity, specific gravity and concentration of the desiccant liquid.

In order for the desiccant liquid to effectively absorb moisture and heat from the first exhaust gas, the specific gravity, concentration, acidity, purity, viscosity and temperature of the absorbent may act as the main factors. For example, when the temperature of the desiccant liquid is below a predetermined temperature range, the desiccant liquid may solidify, and when the temperature of the desiccant liquid is above a predetermined temperature range, it may be in a vapor state.

In this case, the desiccant liquid may be in a state in which it is difficult to absorb moisture and heat from the exhaust gas, and if the concentration of the desiccant liquid is not in the desired range, the moisture and heat absorption rate of the desiccant liquid may be reduced.

In addition, when the desiccant liquid is reused in circulation between the moisture absorption unit (10) and the storage unit (20), the amount of stored desiccant liquid may decrease because the desiccant liquid is naturally consumed.

To compensate for the decrease in the capacity of the desiccant liquid, a dispenser for replenishing the desiccant liquid (70) connected to the storage unit (20) may be provided.

One end of the dispenser (70) is connected to the storage unit (20) through a pipe, and desiccant liquid can be replenished into the storage unit (20) according to at least one of the following parameters: level (24), specific gravity, concentration, acidity , purity, viscosity and temperature of the desiccant liquid contained in the accumulation unit (20).

Such a dispenser (70) may replenish the desiccant liquid in the storage unit (20) when the amount of stored desiccant liquid in the storage unit (20) decreases or the temperature falls outside a predetermined temperature range, or even when at least one of the following: specific gravity , the concentration, acidity, viscosity and purity of the desiccant liquid in the storage unit (20) is outside the specified range.

The heat exchange unit (40) is located on the desiccant liquid supply pipes (P4, P5) connecting the storage unit (20) and the moisture absorption unit (10), and when the desiccant liquid is supplied from the storage unit (20) to the desiccant unit (10), heat can be recovered from the desiccant liquid.

In the heat exchange unit (40), the desiccant liquid and cold water can flow independently through respective pipes, but the pipe through which the desiccant liquid flows and the pipe through which the cold water flows intersect and contact each other, so that mutual heat exchange can occur.

To do this, the heat exchange unit (40) can be connected to the desiccant liquid supply pipes (P4, P5) on one side, and the cold water supply pipe (P12), through which cold water is supplied, and the hot water discharge pipe can be connected on the other side (P14), through which cold water absorbs heat from the desiccant liquid and removes the resulting hot water.

As described above, the exhaust gas heat recovery and white smoke reduction apparatus according to an example of the present invention can generate hot water by heating cold water using the amount of heat absorbed by the first exhaust gas, and use the resulting hot water as life support, etc. which can reduce carbon emissions and save energy.

Such heat exchange unit (40) may include a first heat exchanger (41) and a second heat exchanger (42) connected to each other.

One side of the first heat exchanger (41) is connected to the desiccant liquid supply pipes (P4, P5), the other side is connected to the cold water supply pipe (P12) and the hot water drain pipe (P13, P14), and the second heat exchanger (42) is on one side connected to the hot water exhaust pipes (P13, P14) connected to the first heat exchanger (41), and the other side may be connected to the steam exhaust pipe (P10) of the gas-liquid separation unit (90). Here, high temperature steam generated in the gas-liquid separation unit (90) can be supplied to the steam exhaust pipe (P10).

Thus, in the first heat exchanger (41), the desiccant liquid supply pipes (P4, P5) and the cold water supply pipe (P12) intersect with each other, and in the first heat exchanger (41), the hot water exhaust pipe (P14) and the steam exhaust pipe (P10) may overlap each other.

Accordingly, the first heat exchanger (41) absorbs the heat of the desiccant liquid with cold water, converts the cold water into hot water, and the second heat exchanger (42) uses the steam discharged through the steam exhaust pipe (P10), the temperature of the hot water leaving the first heat exchanger ( 41), is further increased and can be discharged through the hot water drain pipe (P14).

Thus, the heat exchange unit (40) can generate hot water with a temperature of 70°C to 90°C by absorbing the heat of the desiccant liquid into the cold water through the first and second heat exchangers (41, 42).

Here, at least one of the cold water supply pipe (P12) and the hot water exhaust pipe (P14) connected to the heat exchange unit (40) may be connected to the precooler (30). For example, a cold water supply pipe (P12) connected to the first heat exchanger (41) may be connected to a pre-cooler supply pipe (P31b) and a pre-cooler discharge pipe (P31a), and/or a hot water discharge pipe (P14) connected with the second heat exchanger (42), can be connected to the pre-cooler supply pipe (P35b) and the pre-cooler discharge pipe (P35a). This will be described in detail below when describing the precooler (30).

The regeneration unit (80) serves to improve the chemical properties of the desiccant liquid capable of absorbing moisture. For this purpose, the regeneration unit (80) on one side has a desiccant liquid regeneration pipe (P7), into which the desiccant liquid is supplied from the storage unit (20), and a separation pipe an outlet pipe (P8), through which the desiccant liquid heated by steam and separated from the vapor is discharged, and on the other hand, a steam supply pipe (P15), through which high-temperature steam is supplied, and a steam outlet pipe (P16), through which condensation and removal occurs pair. In the regeneration unit (80), the desiccant liquid regeneration pipe (P7) and the steam supply pipe (P15) may cross each other. That is, in the regenerating unit, the desiccant liquid and steam flow through the pipes independently of each other, but each pipe intersects and touches each other, so that heat exchange with each other is possible. In the regeneration unit (80), the moisture contained in the desiccant liquid can be separated and released as water vapor by heating the desiccant liquid with high temperature steam. Accordingly, the desiccant liquid with a high moisture content in the regeneration unit (80) may change its chemical characteristics to a desiccant liquid with a relatively low moisture content when water vapor is released.

As described above, the exhaust gas heat recovery and white smoke reduction apparatus according to an example of the present invention is used to absorb moisture and heat of the first exhaust gas by repeatedly circulating the desiccant liquid through the desiccant absorption unit (10) and the storage unit (20). However, repeated use may degrade the desiccant properties of the desiccant liquid.

Although the case where the regeneration unit (80) heats the desiccant liquid with steam has been described as an example, the present invention is not necessarily limited to steam, and instead of steam, high-temperature gas, oil vapor or liquid, etc. can be used to heat the desiccant liquid, etc.

In the present invention, in order to prevent deterioration in the moisture absorption performance of the desiccant liquid, the desiccant liquid can be heated through the regeneration unit (80), so that the chemical properties of the desiccant liquid capable of holding moisture can be improved.

The gas and liquid separation unit (90) is made in the form of a cylinder, inside of which there is a cavity, on one side there is a separation separation pipe (P8), and on the other side there is a steam exhaust pipe (P10) for removing water vapor, and a moisture recovery pipe ( P9), absorbing moisture, to return moisture separated from water vapor to the storage unit (20). Here, the exhaust separation pipe (P8) can be connected to the side, the steam exhaust pipe (P10) to the top, and the moisture recovery pipe (P9) to the bottom of the gas-liquid separation unit (90).

Accordingly, when the desiccant liquid discharged from the regeneration unit (80) and the water vapor separated from the desiccant liquid are introduced through the discharge separation pipe (P8), the desiccant liquid may be located at the bottom and the water vapor at the top of the gas separation unit and liquids (90).

Accordingly, the steam coming out of the gas-liquid separation unit (90) is discharged through the steam exhaust pipe (P10) connected to the top, and as shown in Fig. 1, the steam exhaust pipe (P10) is connected to the second heat exchanger (42) and can be used for additional heating of hot water.

The moisture-absorbing liquid discharged from the gas-liquid separation unit (90) can be returned to the storage unit (20) through the moisture recovery pipe (P9) in a state in which the chemical properties that may contain moisture are improved.

The emergency control unit (50), in cases where the moisture absorption unit (10) or the heat exchange unit (40) does not work properly, or the temperature or concentration of the desiccant liquid is outside the required range, can directly release the first exhaust gas into the air through the chimney ( 2), bypassing the moisture absorption block (10).

For this purpose, an emergency control unit (50) may be provided at the end of the exhaust gas supply pipe (P1) and at the end of the exhaust gas discharge pipe (P2), and an exhaust gas supply valve (51a) connected to the exhaust gas supply pipe ( P1), an exhaust valve (51b) connected to the exhaust pipe (P2), and a moisture absorption unit bypass valve (52) provided between the exhaust gas supply valve (51a) and the exhaust valve (51b).

Here, the bypass valve (52) of the moisture absorption unit operates opposite the exhaust gas supply valve (51a) and the exhaust valve (51b), and can be controlled so that the exhaust gases are discharged outside without passing through the first exhaust moisture absorption unit (10 ).

For example, when the exhaust gas supply valve (51a) and the exhaust gas release valve (51b) are turned on, the moisture absorption unit bypass valve can be turned off. In this case, the first exhaust gas supplied from the exhaust gas supply source (1) is supplied to the moisture absorption unit (10) through the exhaust gas supply pipe (P1), and the second exhaust gas processed in the moisture absorption unit (10) can be discharged in the direction of the chimney (2) through the exhaust gas pipe (P2).

However, in an emergency situation, the exhaust gas supply valve (51a) and exhaust gas release valve (51b) can be turned off, the moisture absorption unit bypass valve (52) is turned on, then the first exhaust gas does not pass through the moisture absorption unit (10) and it can be released into the atmosphere directly through the chimney (2).

A fan (60) is located on the exhaust gas exhaust pipe (P2) between the moisture absorption unit (10) and the exhaust valve (51b), and it can increase the discharge speed of the second exhaust gas discharged from the moisture absorption unit (10).

The pre-cooler (30) is installed on the exhaust gas supply pipe (P1), it can cool the heat of the first exhaust gas with influent water supplied from outside, and supply the cooled first exhaust gas to the moisture absorption unit (10).

In particular, as shown in Fig. 2, when the first exhaust gas is introduced through the exhaust gas supply pipe (P1) at a first temperature (T1) above 100°C, the pre-cooler (30) can cool the first exhaust gas from a first temperature (T1) above 100°C to a second temperature ( T2) - between the first temperature (T1) and 100°C.

For example, the second temperature (T2) of the first exhaust gas cooled by the precooler (30) may be from 110°C to 120°C. In the case where the first exhaust gas is supplied to the moisture absorption unit (10) within this temperature range, the reactions of heat absorption and absorption by the desiccant liquid can be very effective.

The temperature of the second exhaust gas from which heat and moisture are recovered by the desiccant liquid in the moisture absorption unit (10) may be a third temperature (T3) below 100°C, and the range of the third temperature (T3) may be, for example, from 50°C to 70°C.

As shown in Fig. 2, the pre-cooler (30) cools the first exhaust gas having a first temperature (T1) above 100°C to a second temperature (T2) above 100°C, and can supply the first exhaust gas having an optimal temperature to the moisture absorption unit ( 10).

This pre-cooler (30) controls the refrigeration more effectively, and for more efficient refrigeration control, it can be connected to the cold water supply pipe (P12) or the hot water return pipe (P14), so that cold or hot water can be supplied as inlet water .

In addition, the incoming water that has absorbed heat from the first exhaust gas in the pre-cooler (30) can be discharged through the cold water supply pipe (P12) or the hot water exhaust pipe (P14).

Specifically, a precooler supply pipe (P31b), through which incoming water is supplied, and a precooler outlet pipe (P31a), through which incoming water is discharged, may be connected to the precooler (30).

Here, the pre-cooler supply pipe (P31b) is connected to the cold water supply pipe (P12) or the hot water discharge pipe (P14), and the pre-cooler discharge pipe (P31a) can be connected to the pipe to which the pre-cooler supply pipe (P31b) is connected. , from the cold water supply pipe (P12) or the hot water drain pipe (P14).

As shown in Fig. 1, for example, the pre-cooler supply pipe (P31b) and the pre-cooler discharge pipe (P31a) can be connected to the cold water supply pipe (P12), and cold water can be supplied to the pre-cooler (30) through the pre-cooler supply pipe (P31b), and the cold water heated by the first exhaust gas in the precooler (30) can be returned to the cold water supply pipe (P12) through the precooler outlet pipe (P31a) and supplied to the first heat exchanger (41).

Here, the precooler supply pipe (P31b) may include a precooler supply valve (31b) to control the supply of incoming water, and the precooler discharge pipe (P31a) may include a precooler discharge valve (31a) to control the discharge of incoming water.

In addition, a precooler bypass valve (32) may be provided between a portion of the cold water supply pipe (P12) to which the precooler supply pipe (P31b) is connected and a portion to which the precooler discharge pipe (P31a) is connected. The precooler bypass valve (32) can operate in the opposite direction from the precooler supply valve (31b) and the precooler outlet valve (31a).

For example, when the pre-cooler supply valve (31b) and the pre-cooler discharge valve (31a) are open, the pre-cooler bypass valve (32) can be closed, and thus the cold water supplied to the cold water supply pipe (P12) is supplied to a pre-cooler (30) to cool the first exhaust gas, and cold water absorbing heat from the first exhaust gas may be supplied to the first heat exchanger (41).

Conversely, when the pre-cooler supply valve (31b) and the pre-cooler discharge valve (31a) are closed, the pre-cooler bypass valve (32) can be opened, and thus the cold water supplied to the cold water supply pipe (P12) can be supplied directly to the first heat exchanger (41) without supplying to the pre-cooler 30.

As described above, the present invention includes a pre-cooler supply valve (31b), a pre-cooler release valve (31a) and a pre-cooler bypass valve (32), and turning on or stopping the pre-cooler (30) accordingly responding to the first temperature (T1) the first exhaust gas supplied at different temperatures depending on the season, the efficiency of the moisture absorption unit (10) can be further optimized.

In Fig. 1 describes as an example a case where the pre-cooler (30) of the present invention is connected only to the cold water supply pipe (P12), but the pre-cooler (30) is not necessarily limited to this and can be connected to the hot water discharge pipe (P14).

Rice. 3 is a diagram for explaining the first modified example in which the pre-cooler (30) is connected to the hot water discharge pipe (P14) in the first embodiment of the present invention.

In Fig. 3 and further points that coincide with the content described in Fig. 1 and 2 are replaced by descriptions of Figures 1 and 2, and the excellent points are mainly described.

In a first modification of the first embodiment of the present invention, as shown in Fig. 3, the pre-cooler supply pipe (P35a) and the pre-cooler discharge pipe (P35b) can be connected to the hot water discharge pipe (P14).

Here, the pre-cooler supply pipe (P35a) is connected to the hot water discharge pipe (P14), the pre-cooler discharge pipe (P35b) can be connected to the rear end of the hot water discharge pipe (P14) to which the pre-cooler supply pipe (P35a) is connected, and the pre-cooler supply pipe (P35a) may be provided with a pre-cooler supply valve (35a), and a pre-cooler discharge valve (35b) may be provided on the pre-cooler discharge pipe (P35b).

In addition, a pre-cooler bypass valve (36) may be provided between a portion of the hot water drain pipe (P14) to which the pre-cooler supply pipe (P35a) is connected and a portion to which the pre-cooler discharge pipe (P35b) is connected.

Accordingly, in the first modification of the present invention, it is also possible to supply hot water with a temperature of 70° C. to 90° C. discharged through the second heat exchanger (42) to the pre-cooler (30) to cool the first exhaust gas having a first temperature (T1) of 100 °C or higher.

Moreover, the present invention can also be implemented by combining the first and second embodiments.

Rice. 4 is a diagram for explaining a second modified example in which the pre-cooler (30) is connected to a cold water supply pipe (P12) and a hot water drain pipe (P14) in the first embodiment of the present invention.

As shown in Fig. 4, in the present invention, according to the second modified example, cold water and hot water can be supplied to the pre-cooler (30) optionally.

Specifically, in the second modification, the precooler supply pipe may include first and second precooler supply pipes (P31b, P35a), and the precooler outlet pipe may include first and second precooler outlet pipes (P31a, P35b).

The first precooler supply pipe (P31b) and the first precooler outlet pipe (P31a) can be connected to the cold water supply pipe (P12), and the second precooler supply pipe (P35a) and the second precooler outlet pipe (P35b) can be connected with hot water outlet pipe (P14).

In addition, each of the first and second precooler supply pipes (P31b, P35a) may include first and second precooler supply valves (31b, 35a), and each of the first and second precooler outlet pipes (P31a, P35b) may include include the first and second precooler outlet valves (31a, P35b).

In addition, a first precooler bypass valve (32) may be provided in the cold water supply pipe (P12), and a second precooler bypass valve (36) may be provided in the hot water outlet pipe (P14).

Accordingly, in the second modified example, to supply cold water to the precooler (30), the first precooler supply valve (31b) and the first precooler outlet valve (31a) are opened, and the first precooler bypass valve (32) is closed, to the precooler Cooler (30) is supplied with cold water, and to block hot water supply to the precooler (30), the second precooler supply valve (35a) and the second precooler outlet valve (31b) are closed, and the second precooler bypass valve (36) can be disabled.

Conversely, to supply hot water to the precooler (30), the second precooler supply valve (35a) and the second precooler outlet valve (35b) are opened, and the second precooler bypass valve (36) is closed to the precooler (30). hot water is supplied, and to block the supply of cold water to the precooler (30), the first precooler supply valve (31b) and the first precooler outlet valve (31a) are closed, and the first precooler bypass valve (32) can be turned off.

In this second modified example, the first temperature (T1) of the first exhaust gas may vary depending on circumstances such as the season, the process of the previous stage, the type of the first exhaust gas, etc., so that even if the first temperature (T1) of the first exhaust gas is input differently, in response, cold or hot water can be selectively supplied to the pre-cooler (30), thereby the efficiency and performance of the exhaust gas heat recovery and white smoke reduction device can be further improved.

Rice. 5 is a diagram for explaining an exhaust heat recovery and white smoke reduction apparatus with a rear heater according to the second embodiment of the present invention.

As shown in Fig. 5, the exhaust heat recovery and white smoke reduction apparatus according to the second embodiment of the present invention may further include a heater (100) connected to the exhaust pipe (P2) for heating the second exhaust gas at the rear end of the moisture absorption unit (10) .

The heater (100) can heat the second exhaust gas entering the exhaust pipe (P2) and discharge it into the chimney (2). For this purpose, the second exhaust gas may be supplied to one side of the heater (100), and steam or incoming water having a higher temperature than the second exhaust gas may be supplied to the other side of the heater (100).

For example, as shown in Fig. 5, the heater supply pipe (P110a) and the heater outlet pipe (P110b) are connected to the other side of the heater (100), the heater supply pipe (P110a) is connected to the steam exhaust pipe (P10), and the heater outlet pipe (P110b) can be connected to pipe (P11), through which water vapor is condensed and removed from the second heat exchanger (42).

That is, the heater outlet pipe (P110b) may be connected to a condensate pipe (P11) connected to the second heat exchanger (42). In the condensate pipe (P11), the condensed water can be drained, while steam supplied to the second heat exchanger 42 through the steam exhaust pipe (P10) heats the incoming water from the first heat exchanger (P41). The heater outlet pipe (P110b) can be connected to the condensate pipe (P11). Accordingly, the second exhaust gas enters one side of the heater (100), and water vapor having a higher temperature than the second exhaust gas enters the other side of the heater (100) through the heater supply pipe (P110a), the second exhaust gas is heated by the heater ( 100), and the temperature of the second exhaust gas may increase.

The second exhaust gas may be exhaust gas dried at a low temperature, at which moisture and heat are recovered in the moisture absorption unit (10). For example, the temperature of the second exhaust gas may be from about 50°C to 60°C in a dry state with a small amount of moisture.

Thus, in the case of dry exhaust gas at a temperature of about 50°C - 60°C, the dew point can be relatively reduced to 25°C - 35°C. In summer, when the air temperature is about 20°C-35°C, the second exhaust gas, which has a low temperature, is not easy to cool below the dew point temperature, so even if it is discharged into the atmosphere through the chimney (2), the white smoke may not form.

However, in winter, since the air temperature is approximately -10°C to 5°C, when dry second exhaust gases are discharged at a temperature of 50°C - 60°C, the dew point is reached in a short time during the exhaust through the chimney (2). , formed between 25°C and 35°C, and the formation of white smoke is possible when exhausted through the chimney (2) and released into the atmosphere.

However, as in the present invention, when the temperature of the second exhaust gas is raised from 80° C. to 100° C. by heating the second exhaust gas through the heater (100), a state above the dew point remains for a while even after exiting the chimney (2), and This way you can suppress the formation of white smoke.

Thus, the second embodiment of the present invention further includes a heater (100) to further suppress the generation of white smoke.

In addition, the second embodiment of the present invention has been described as an example in which the heater (100) is further provided in the first embodiment of the present invention shown in Fig. 1 as an example, but the present invention is not limited to this, and the heater (100) can be further provided in the same manner as the first modified example and the second modified example of the first embodiment.

Therefore, the present invention is equipped with a pre-cooler (30) to absorb the heat of the first exhaust gas at the front end of the desiccant unit (10), the waste heat from the exhaust gas can be more effectively recovered, and by achieving the optimum temperature of the first exhaust gas supplied to the absorption unit moisture (10), the moisture absorption unit (10) can sufficiently absorb moisture and latent heat from the exhaust gas, thereby further improving the efficiency of latent heat recovery and white smoke reduction.

In addition, by providing a heater (100) for heating the second exhaust gas at the rear end of the moisture absorption unit (10), the occurrence of white smoke can be more effectively suppressed even in winter.

In addition, in Fig. 5 shows as an example the case where the heater supply pipe (P110a) connected to the heater (100) is connected to the steam exhaust pipe (P10), but the present invention is not necessarily limited to this, and the heater supply pipe (P110a) may also be connected to hot water drain pipe (P14). Accordingly, the heater (100) may also heat the second exhaust gas to obtain hot water from the hot water exhaust pipe (P14).

The technical features disclosed in each embodiment of the present invention are not limited to the respective embodiment, and unless they are incompatible with each other, the technical features disclosed in each embodiment can be combined and applied to other embodiments.

Thus, each embodiment generally describes each technical feature, but each technical feature may be combined and used in combination with one another as long as they are not mutually incompatible.

The present invention is not limited to the above-described embodiments and the accompanying drawings, and various modifications and variations are possible from the point of view of those skilled in the art to which the present invention relates. Therefore, the scope of this invention should be determined not only by the claims of this specification, but also by the claims equivalent to the claims of this specification.

Claims (42)

1. An exhaust heat recovery and white smoke reduction device having a pre-cooler containing a moisture absorption unit, which, receiving the first exhaust gas containing high-temperature water vapor through the exhaust gas supply pipe, absorbs moisture and heat from the first exhaust gas through the moisture-absorbing liquid, discharges the second exhaust gas in a state in which the first exhaust gas is dried at a low temperature through exhaust gas outlet pipe; a storage unit in which the desiccant liquid in contact with the first exhaust gas is discharged from the moisture absorption unit and stored; And a pre-cooler provided on the exhaust gas supply pipe for cooling the heat of the first exhaust gas with supply water supplied from outside; to recover heat from the desiccant liquid, the device additionally includes a heat exchange unit, which is a connected desiccant liquid supply pipe on one side, through which the desiccant liquid is supplied from the storage unit to the moisture absorption unit, and a cold water supply pipe, through which cold water is supplied to the other side, and the cold water absorbs the heat of the dehumidifier, and to which a hot water discharge pipe is connected to absorb the heat and discharge the generated hot water; wherein the device also includes a regeneration unit, which is connected on one side to a desiccant liquid regeneration pipe into which the desiccant liquid flows from the accumulation unit, and on the other side to a steam pipe through which high-temperature steam is supplied and heated by the steam to produce a desiccant, and which is connected to a separation outlet pipe through which the desiccant liquid and steam separated from the desiccant liquid are discharged; and a gas-liquid separation unit, to which a separation outlet pipe is connected on one side, and a steam exhaust pipe for releasing water vapor and a desiccant liquid recovery pipe for recovering moisture separated from the water vapor are connected to the accumulation unit; the heat exchange unit includes a first heat exchanger and a second heat exchanger, one side of the first heat exchanger is connected to a desiccant liquid supply pipe, and the other side is connected to a cold water supply pipe and a hot water discharge pipe, and one side of the second heat exchanger is connected to a hot water exhaust pipe, and the other side may be connected to a steam exhaust pipe of the gas-liquid separator; Connected to the precooler are a precooler inlet pipe through which incoming water is supplied, and a precooler outlet pipe through which incoming water is discharged; a cold water supply pipe connected to the first heat exchanger is connected to a pre-cooler supply pipe and a pre-cooler discharge pipe. 2. The apparatus of claim 1, wherein in the pre-cooler the first exhaust gas can be cooled from a first temperature above 100°C to a second temperature between the first temperature and 100°C. 3. The device according to claim 1, in which the precooler inlet pipe is connected to the cold water supply pipe, the precooler inlet valve is turned on to control the incoming water supply, the pre-cooler outlet pipe is connected to the cold water supply pipe and includes a pre-cooler outlet valve to control the release of incoming water; a precooler bypass valve operating opposite the precooler supply valve and a precooler outlet valve may be provided between the portion where the precooler supply pipe is connected and the portion where the precooler discharge pipe is connected to the cold water supply pipe. 4. The device according to claim 3, in which the pre-cooler inlet pipe is connected to the hot water outlet pipe, the pre-cooler supply valve is turned on to control the incoming water supply, the pre-cooler outlet pipe is connected to the hot water outlet pipe and includes a pre-cooler outlet valve that controls the release of incoming water, when cold water is supplied to the pre-cooler, the pre-cooler supply valve and the pre-cooler discharge valve connected to the hot water discharge pipe are closed, and the pre-cooler bypass valve connected to the hot water discharge pipe is turned on, and hot water is supplied to the pre-cooler, the precooler inlet valve and the precooler outlet valve connected to the cold water supply pipe are closed, the precooler bypass valve connected to the cold water supply pipe is turned on. 5. The device according to claim 1, in which an emergency control unit is provided at the end of the exhaust gas supply pipe and at the end of the exhaust gas exhaust pipe for discharging the first exhaust gas outside without passing through the moisture absorption unit. 6. The device according to claim 5, in which the emergency control unit provides an exhaust gas supply valve connected to the exhaust gas supply pipe, an exhaust valve connected to the exhaust pipe, an exhaust gas supply valve and an exhaust gas discharge valve, and operating opposite the exhaust gas supply valve and the exhaust gas discharge valve, a moisture absorption device bypass valve for controlling the discharge of the first exhaust gas to the outside without passing through the moisture absorption device. 7. The device according to claim 5, further comprising a fan located on the exhaust gas exhaust pipe and increasing the discharge speed of the second exhaust gas discharged from the moisture absorption unit. 8. The device according to claim 1, in which the storage unit includes a plurality of partitions provided inside the accumulation unit and directing the flow of desiccant liquid to the desiccant liquid supply pipe, and a filter installed between the plurality of partitions for filtering foreign matter from the desiccant liquid. 9. The device according to claim 8, further including a metering unit, one end of which is connected to the storage unit and replenishes the desiccant liquid into the accumulation unit in accordance with at least one of the following parameters: level, specific gravity, concentration, acidity, purity , viscosity and temperature of the desiccant liquid contained in the accumulation unit. 10. The apparatus of claim 1, wherein a hot water discharge pipe connected to the second heat exchanger is connected to a pre-cooler supply pipe and a pre-cooler discharge pipe. 11. The apparatus of claim 1, further including a heater connected to the exhaust gas exhaust pipe on one side through which the second exhaust gas is introduced to heat and discharge the second exhaust gas. 12. The apparatus of claim 11, wherein a heater supply pipe and a heater outlet pipe are provided on the other side of the heater, the heater supply pipe is connected to the steam exhaust pipe, and the outlet pipe of the heater is connected to a pipe through which water vapor is condensed and discharged from the heat exchange unit. 13. The device according to claim 12, including a heater supply valve provided on the heater supply pipe to control the supply of steam, a heater outlet valve provided on the heater outlet pipe for releasing condensed steam, a part connected to the heater supply pipe on the steam exhaust pipe, and the second heat exchanger, and the steam supply valve to the second heat exchanger, and a heater supply valve and a heater outlet valve, which operate opposite the supply valve of the second heat exchanger. 14. The device according to claim 13, in which, when the heater supply valve and the heater outlet valve are open or closed, the supply valve of the second heat exchanger is closed or, conversely, opened.