KR20170099134A - Selective Catalytic Reduction System for Energy Saving - Google Patents

Abstract

The present invention relates to a selective catalytic reduction (SCR) system to save energy, capable of preventing an SCR reactor from being poisoned and also capable of reducing consumption energy in a catalyst regeneration operation, or a heating and ventilation operation. According to the present invention, in the case of removing contamination generated in a catalyst of the SCR reactor due to ammonium disulfate, which is generated in the SCR reactor as an exhaust gas purification process is underway to remove nitrogen oxide from exhaust gas of an engine by the SCR reactor, to regenerate the catalyst of the SCR reactor, or in the case of maintaining the SCR reactor at a constant temperature to heat and ventilate the SCR reactor, the air heated by waste heat of the exhaust gas of a main or bogie engine is fed to the SCR reactor to remove the contamination from the catalyst of the SCR reactor so as to regenerate the catalyst, or heat and ventilate the SCR reactor; thus preventing the SCR reactor from being poisoned and also reducing energy consumption in the catalyst regeneration operation, or the heating and ventilation operation.

Description

[0001] SCR system for energy saving [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an SCR system for removing nitrogen oxides (NOx) of an engine exhaust gas generated at the time of driving an engine installed in a ship, and particularly, an exhaust gas purifying process for removing nitrogen oxides , It is possible to regenerate the catalyst of the SCR reactor by removing the contamination of the SCR reactor catalyst due to the ammonium sulfonate formed in the SCR reactor or to maintain the SCR reactor at a constant temperature, < / RTI > venting), the air heated by the exhaust gas waste heat of the main engine or the view engine is introduced into the SCR reactor to remove contamination of the SCR reactor catalyst to regenerate the catalyst or to heat and ventilate the SCR reactor To prevent poisoning of the SCR reactor during catalyst regeneration, heating and ventilation operation, and to save energy consumption To an SCR system for energy saving.

Nitrogen oxides and sulfur oxides among exhaust gases emitted from diesel engines commonly used in ships are representative air pollutants subject to emission regulation from the International Maritime Organization (IMO), which is a member of the United Nations (UN).

Nitrogen oxides are NO, NO ₂ , NO ₃ , N ₂ O, N ₂ O ₃ , N ₂ O ₄ and N ₂ O ₅ , but most of the nitrogen oxides are NO and NO ₂ . Sulfur oxides are mainly SO ₂ in which sulfur components contained in fuels such as coal and petroleum are oxidized in the combustion process.

Nitrogen oxides are generated by the reaction of Nitrogen in the combustion process with thermal NOx generated by the reaction of nitrogen and oxygen in the air in the high temperature region, Prompt NOx generated by the reaction of hydrocarbons generated from the fuel with nitrogen in the air, Fuel NOx, which is the amount of NOx in the exhaust gas.

SCR systems have been used to remove nitrogen oxides generated by the combustion reaction of fossil fuels. The SCR system uses ammonia (NH ₃ ) as a reducing agent to reduce nitrogen oxides to nitrogen (N ₂ ) and water (H ₂ O) by passing exhaust gas mixed with a reducing agent through the catalyst layer installed in the SCR reactor.

In particular, in an SCR system for removing nitrogen oxides of an engine exhaust gas by an SCR reactor, an engine exhaust gas is applied to an SCR reactor, decomposing urea into ammonia by a reducing agent injecting module, and applying ammonia to the SCR reactor as a reducing agent , The nitrogen oxide of the engine exhaust gas is reduced to nitrogen (N ₂ ) and water (H ₂ O) using ammonia as a reducing agent in the SCR reactor, and is purified and discharged.

In the SCR system described above, when the purifying treatment for removing the nitrogen oxide of the engine exhaust gas is repeatedly performed by the SCR reactor, the sulfur oxide present in the fuel reacts with the reducing agent ammonia, and thus, the ammonia bisulfate The catalyst in the SCR reactor can not be stably operated by the catalyst in the SCR reactor. In order to purify the engine exhaust gas stably, it is necessary to perform the SCR operation on the outside of the emission control area (ECA) It is necessary to regenerate the catalyst of the SCR reactor by applying heat to the reactor at a temperature of 250 ° C or more and applying heated water or steam to the SCR reactor periodically to remove the contamination of the SCR reactor catalyst.

When the exhaust gas of the main engine is not purified in the SCR reactor on the high seas or the port outside the ECA (Emission Control Area), air heated to 100 ° C or higher (preferably 200 ° C) is introduced into the SCR reactor, It is necessary to prevent the catalyst strength and activity of the SCR reactor due to moisture condensation in the atmosphere from being reduced by heating and venting.

In the SCR system, when the catalyst of the SCR reactor is regenerated or the heating and ventilation of the SCR reactor is proceeded, the temperature of the SCR reactor must be raised to a predetermined temperature by using an electric heater or a burner, .

In the conventional SCR system, in order to reduce the energy required for catalyst regeneration, heating and ventilation of the SCR reactor, the exhaust gas of the engine is introduced into the SCR reactor and the SCR reactor is heated to a predetermined temperature The catalyst regeneration of the SCR reactor and the heating and ventilation of the SCR reactor are applied. However, when the catalyst is regenerated, heated and ventilated by directly introducing the exhaust gas into the SCR reactor, the sulfur contained in the exhaust gas The catalyst of the SCR reactor is poisoned by the sulfur (S) or phosphorus (P) compound, and the activity is lowered.

DISCLOSURE Technical Problem The present invention has been proposed in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide an SCR reactor which is capable of efficiently removing nitrogen oxides of engine exhaust gas, In the case of regenerating the catalyst of the SCR reactor by removing the contamination of one SCR reactor catalyst or heating and venting the SCR reactor by maintaining the SCR reactor at a constant temperature, The air heated by the waste heat of the gas is introduced into the SCR reactor to remove the contamination of the SCR reactor catalyst to regenerate the catalyst or to heat and ventilate the SCR reactor to prevent poisoning of the SCR reactor during catalyst regeneration, And to provide an SCR system for energy saving to reduce energy consumption .

According to a first aspect of the present invention, there is provided a method for regenerating a catalyst by removing contaminants from an SCR reactor catalyst and reducing energy when the catalyst is heated and ventilated An SCR system comprising: a blower for introducing air; an air heater for heating the air introduced from the blower by exhaust gas waste heat of a main engine or a view engine; and an air heater for introducing air heated by the air heater into a urea decomposition chamber A heating air delivery pipe; The heated air introduced into the urea decomposition chamber through the heated air delivery pipe is introduced into the SCR reactor via a mixer and the main engine exhaust gas and the view engine exhaust gas used for heating the air in the air heater are supplied to respective separate exhaust And discharging the gas through a gas discharge pipe.

According to the first aspect of the present invention, the heated air introduced into the urea decomposition chamber through the heated air delivery pipe is heated by the urea decomposition burner.

According to the first aspect of the present invention, the apparatus further includes a heater for heating the heated air introduced into the urea decomposition chamber through the heated air delivery pipe using energy.

According to the first aspect of the present invention, there is provided an air heater for a vehicle, comprising: a viewing engine exhaust gas entry / exit member for allowing / exiting a view engine exhaust gas into / from the air heater; a main engine exhaust gas entry / And an air inlet member for allowing the air to enter and exit the heater.

According to a second aspect of the present invention, there is provided an SCR system for recovering catalyst to remove contamination of an SCR reactor catalyst or for reducing energy when heating and ventilation are performed for an SCR reactor, A blower for introducing the air supplied through the heated air circulation pipe into the air heater, a blower for blowing air introduced from the blower into the air heater, And a heated air delivery pipe for introducing the air heated by the air heater into the urea decomposition chamber; The heated air introduced into the urea decomposition chamber through the heated air delivery pipe is introduced into the SCR reactor via a mixer and the main engine exhaust gas and the view engine exhaust gas used for heating the air in the air heater are supplied to respective separate exhaust And discharging the gas through a gas discharge pipe.

According to the second aspect of the present invention, the heated air introduced into the urea decomposition chamber through the heated air delivery pipe is heated by the urea decomposition burner.

According to a second aspect of the present invention, there is further provided a heater for heating the heated air introduced into the urea decomposition chamber through the heated air delivery pipe by using energy.

According to a second aspect of the present invention, there is further provided a valve for interrupting the inflow of heated air from the SCR reactor to the heated air circulation pipe.

According to a second aspect of the present invention, there is provided an air heater for a vehicle, comprising: a view engine exhaust gas entry / exit member for inserting / extracting a view engine exhaust gas into / from the air heater; a main engine exhaust gas entry / And an air inlet member for allowing the air to enter and exit the heater.

According to the present invention, as the exhaust gas purifying treatment for removing nitrogen oxides of the engine exhaust gas is performed by the SCR reactor, contamination of the SCR reactor catalyst due to the ammonium di-sulphate generated in the SCR reactor is removed, The air heated by the exhaust gas waste heat of the main engine or the view engine is introduced into the SCR reactor so that the contamination of the SCR reactor catalyst can be prevented The catalyst is regenerated or the SCR reactor is heated and ventilated. Therefore, poisoning of the SCR reactor is prevented during regeneration of catalyst, heating and ventilation operation, and energy consumption is reduced.

1 is a diagram illustrating an SCR system for energy saving according to a first embodiment of the present invention.
2 is a diagram illustrating an SCR system for energy saving according to a second embodiment of the present invention.
3 is a diagram illustrating an SCR system for energy saving according to a third embodiment of the present invention.
4 is a diagram illustrating an SCR system for energy saving according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the present invention is not limited to the technical spirit and essential structure and operation of the present invention.

The SCR system 100 for energy saving according to the first embodiment of the present invention includes a main engine 10, an SCR reactor 20, a mixer 30, a urea decomposition chamber 40, A burner 45 for decomposing urea, an air heater 50 and a blower 60.

The mixer 30 receives the exhaust gas of the main engine 10 for generating the propulsion force of the ship and receives the main engine exhaust gas through the exhaust gas receiver 11 and the turbine 15-1 of the turbocharger 15 The ammonia hydrolyzed from the urea decomposition chamber 40 is supplied to the SCR reactor 20 by mixing the main engine exhaust gas and the ammonia from the urea distribution chamber 40 into the SCR reactor 20, Thereby removing nitrogen oxides from the main engine exhaust gas. The mixer 30 serves to allow the ammonia produced in the urea decomposition chamber 40 to be uniformly mixed with the main engine exhaust gas and supplied to the SCR reactor 20. The mixer 30 may be in the form of a chamber, Ammonia Injection Grid) is installed on the exhaust gas pipe wall in the form of a nozzle, and a baffle for flow uniformity can be installed on the inside of the pipe.

The SCR reactor 20 is installed at the rear end of a turbocharger 15 that provides compression and suction to the main engine 10. [ The turbocharger 15 comprises a turbine 15-1 and a compressor 15-2. The turbine 15-1 is driven using the flow energy of the exhaust gas of the main engine 10 to drive the compressor 15-2 and the compressor 15-2 is driven by the turbine 15-1, And supplies it to the main engine 10 to increase the output of the main engine 10. [ The exhaust gas receiver 11 is installed at the outlet of the exhaust manifold of the main engine 10 to store the exhaust gas and apply the exhaust gas to the turbine 15-1, And the intake air receiver 12 stores the intake air compressed by the compressor 15-2 and applies the intake air to the main engine 10 through the intake pipe to increase the output of the main engine 10 do.

The mixer 30 receives the main engine exhaust gas discharged from the exhaust gas receiver 11 and the main engine exhaust gas discharged from the turbine 15-1 of the turbocharger 15 through the valve V15, Ammonia is supplied from the decomposition chamber 40 to the SCR reactor 20 by mixing the main engine exhaust gas with ammonia to remove NO x from the main engine exhaust gas using ammonia as a reducing agent in the SCR reactor 20 Thereby purifying the main engine exhaust gas.

At this time, the urea decomposition chamber 40 receives the urea aqueous solution and the air, injects the urea aqueous solution into the chamber thereof in a spray form, and supplies the main engine exhaust gas, which is supplied from the exhaust gas receiver 11 through the valve V25, The air heated by the burner 45 is supplied to the inside of the chamber and the urea is hydrolyzed by the heat of the main engine exhaust gas and the heated air to convert it into ammonia to be supplied to the SCR reactor 20 through the mixer 30 as a reducing agent The ammonia from the urea decomposition chamber 40 is applied to the SCR reactor 20 via the mixer 30 together with the heated gas when the ammonia is supplied to the SCR reactor 20, SCR reactor 20, and is applied to the SCR reactor 20. In this case,

The main engine exhaust gas purified in the SCR reactor 20 is discharged to the outside through the valves V11 and V12.

On the other hand, when the ship is traveling on the high seas outside the Emission Control Area (ECA), the SCR system 100 bypasses the SCR reactor 20 without cleaning the main engine exhaust gas by the SCR reactor 20 When the main engine exhaust gas is not purified by the SCR reactor 20 on the pollution outside the ECA, the SCR reactor 20 is heated to a temperature of 250 ° C or higher and the SCR reactor 20 The catalyst regeneration operation for regenerating the catalyst in the SCR reactor 20 is performed by removing the contamination of the catalyst of the SCR reactor 20 periodically by applying heated water or steam or the like.

In order to prevent the catalyst strength and activity of the SCR reactor 20 from being reduced in the state where the exhaust gas of the main engine is not purified in the SCR reactor 20 on the high seas or the port outside the ECA, Air heated to 100 ° C or higher (preferably 200 ° C) flows into the reactor 20, and the heating and ventilating operation for the SCR reactor 20 proceeds.

In this way, when the catalyst regeneration operation is performed or the heating and ventilating operation proceeds, the SCR system 100 heats the air by the waste heat of the exhaust gas of the main engine 10 or the view engine, Air is introduced into the urea decomposition chamber 40 through the heated air delivery pipe P13 and the air heated by the exhaust gas waste heat is passed through the urea decomposition chamber 40 and the mixer 30 to the SCR reactor 20, Thereby preventing poisoning of the SCR reactor 20 and reducing energy consumption during catalyst regeneration, heating, and ventilation operation.

In the SCR system 100, a plurality of valves (not shown) for interrupting the air flow into and out of the air heater 50 for heating the air heater 50 using the exhaust gas of the main engine or the view engine The valves V13 to V22 are opened and closed under the control of a controller (not shown) to interrupt airflow and exhaust gas to and from the air heater 50. The valves V25 and V26 provided in the SCR system 100 are also controlled and opened by the controller.

The valves V20 to V22 are used as an engine exhaust gas interrupting valve for interrupting the entrance and exit of the engine exhaust gas to and from the air heater 50. The valves V20 to V22 are opened and closed under the control of the controller, Control the exhaust gas entry and exit. The valve V22 is closed and the valve V21 and the valve V20 are opened so that the exhaust gas from the engine exhaust pipe P12 flows into the valve V21 The engine exhaust gas flowing into the air heater 50 through the pipe P22 and exhausted from the air heater 50 is exhausted through the pipe P21 and the valve V20 via the exhaust pipe P12 .

The valves V13 to V15 are used as a main engine exhaust gas interrupting valve for interrupting the entrance and exit of the main engine exhaust gas to the air heater 50 and are opened and closed under the control of the controller, Control the exhaust gas entry and exit. The valve V15 is closed and the valve V13 and the valve V14 are opened so that the exhaust gas from the main engine exhaust pipe P11 is exhausted from the valve V14 The main engine exhaust gas flowing into the air heater 50 through the pipe P14 and discharged from the air heater 50 is discharged to the outside through the valve V13.

The valves V16 to V19 are used as an air interrupting valve for interrupting the entry and exit of air to and from the air heater 50. The valves V16 to V19 are opened and closed under the control of the controller to interrupt air flow to and from the air heater 50. When the air from the blower 60 is introduced into the air heater 50 in a state in which the exhaust gas of the engine exhausts from the air heater 50 and the air heater 50 heats the air by the engine exhaust gas The valves V17 and V18 are closed and the valves V16 and V19 are opened so that the air from the blower 60 flows into the air heater 50 through the valve V16 and the pipe P23, The air discharged from the discharge port 50 is discharged to the urea decomposition chamber 40 via the pipe P14 and the valve V19 via the heated air discharge pipe P13. The air from the blower 60 is introduced into the air heater 50 while the main engine exhaust gas flows into and out of the air heater 50 to heat the air by the main engine exhaust gas in the air heater 50 The valves V16 and V19 are closed and the valves V17 and V18 are opened so that the air from the blower 60 flows into the air heater 50 through the valve V17 and the pipe P21, The air discharged from the air heater 50 is discharged to the urea decomposition chamber 40 via the pipe P22 and the valve V18 via the heated air delivery pipe P13.

The SCR system 100 controls the valve V25 by the controller when the exhaust gas of the main engine 10 is discharged directly from the bypass pipe P14 without purifying the exhaust gas from the main engine 10 by the SCR reactor 20 on the outside of the ECA. The main engine exhaust gas discharged from the exhaust gas receiver 11 is prevented from flowing into the urea decomposition chamber 40. [

The heated air introduced into the SCR reactor 20 from the air heater 50 via the heated air delivery pipe P13, the urea decomposition chamber 40 and the mixer 30 is supplied to the SCR reactor 20 And then discharged to the outside through valves (V11, V12) provided at the rear end of the SCR reactor (20).

The SCR system 100 is operated in the SCR reactor 20 in a state of discharging the main engine exhaust gas through the bypass pipe P14 bypassing the SCR reactor 20 without purification treatment by the SCR reactor 20 on the outside of the ECA. The valve V25 is closed and the valves V20 and V21 corresponding to the valves for interrupting the exhaust gas of the engine are closed, The valve V15 corresponding to the engine exhaust gas interrupting valve is closed and the valves V13 and V14 are opened to apply the main engine exhaust gas from the bypass exhaust pipe P14 to the air heater 50, The valves V17 and V18 are closed and the air from the blower 60 is supplied to the air heater 50 through the valve V17 and the pipe P21 And the waste heat of the main engine exhaust gas in the air heater 50 is heated to the air The air heated by the air heater 50 is introduced into the urea decomposition chamber 40 via the pipe P22 and the valve V18 via the heated air delivery pipe P13 so that the air heated by the air heater 50 is decomposed into urea decomposition Is applied to the SCR reactor (20) via the chamber (40) and the mixer (30) to maintain the SCR reactor (20) at a constant temperature.

If the air heated by the air heater 50 is directly introduced into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30, the internal temperature of the SCR reactor 20 is heated to 100 ° C. or higher Therefore, it is possible to heat and ventilate the SCR reactor 20, thereby reducing the catalyst strength and activity reduction of the SCR reactor 20 due to moisture condensation in the atmosphere.

When the air heated by the air heater 50 flowing into the urea decomposition chamber 40 is heated by the urea decomposition burner 45 and applied to the SCR reactor 20 via the mixer 30, It is possible to regenerate the catalyst of the SCR reactor 20 while reducing the energy consumption of the burner 45 for decomposing urea since the internal temperature of the SCR reactor 20 can be heated to 250 캜 or more.

Then, the SCR system 100 stops the main engine operation at the port and drives the view engine for operating the generator, so that the SCR system 100 can control the SCR reactor 20 in a state of discharging the view engine exhaust gas through the view engine exhaust pipe P12. The valve V25 is closed and the valves V13 to V15 corresponding to the main engine exhaust gas interrupting valve are closed and the valve V22 corresponding to the engine exhaust gas interrupting valve is closed. And the valves V20 and V21 are opened to apply the engine exhaust gas from the view engine exhaust pipe P12 to the air heater 50 and the valves V17 and V18 corresponding to the air interception valves, And the valves V16 and V19 are opened to allow the air from the blower 60 to flow into the air heater 50 through the valve V16 and the pipe P23, Heat exchange of the waste heat of the gas to the corresponding air The air heated by the air heater 50 is introduced into the urea decomposition chamber 40 by flowing the heated air through the pipe P24 and the valve V19 to the urea decomposition chamber 40 via the heated air delivery pipe P13, And the mixer 30 to the SCR reactor 20 to maintain the SCR reactor 20 at a constant temperature.

If the air heated by the air heater 50 is directly introduced into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30, the internal temperature of the SCR reactor 20 is heated to 100 ° C. or higher Therefore, it is possible to heat and ventilate the SCR reactor 20, thereby reducing the catalyst strength and activity reduction of the SCR reactor 20 due to moisture condensation in the atmosphere.

The SCR system 200 for energy saving according to the second embodiment of the present invention includes a main engine 10, an SCR reactor 20, a mixer 30, a urea decomposition chamber 40 A burner 45 for decomposing urea, an air heater 50, a blower 60 and a heater 70.

The SCR system 200 according to the second embodiment of the present invention differs from the SCR system 100 of the first embodiment in that the heating air delivery pipe P13 is further provided with a heater 70, Is the same as the SCR system 100 of the first embodiment illustrated in Fig.

In the SCR system 200 of the second embodiment, components having the same reference numerals as those of the SCR system 100 of the first embodiment have the same functions and functions, and therefore, the description thereof will be omitted for the convenience of explanation.

The SCR system 200 controls the plurality of valves V13 to V22 for interrupting the entry and exit of air and exhaust gas into the air heater 50 in the same manner as described above, and a description thereof will be omitted.

The SCR system 200 includes a heater 70 in a heated air delivery line P13 for introducing the heated air from the air heater 50 into the urea decomposition chamber 40. The heater 70 is controlled by the controller The air from the air heater 50 is heated and applied to the urea decomposition chamber 40. [

The SCR system 200 is operated in the SCR reactor 20 in a state of discharging the main engine exhaust gas through the bypass pipe P14 bypassing the SCR reactor 20 without purification treatment by the SCR reactor 20 on the outside of the ECA. And the main engine is stopped at the port to drive the view engine for starting the generator and the SCR reactor 20 is operated in a state of discharging the view engine exhaust gas through the view engine exhaust pipe P12 The air heated by the waste heat of the main engine or the exhaust gas of the view engine in the air heater 50 is not heated by the heater 70 but heated via the heated air delivery pipe P13 The internal temperature of the SCR reactor 20 is maintained at 100 ° C or higher by flowing into the urea decomposition chamber 40 as it is and introducing the heated air into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30 Maintained by a heating and ventilation operation proceeds to the SCR reactor 20.

In addition, the SCR system 200 can be operated in a state where the main engine exhaust gas is not purified by the SCR reactor 20 on the pollution outside the ECA but is discharged through the bypass exhaust pipe P14 bypassing the SCR reactor 20, The air heated by the waste heat of the main engine exhaust gas in the air heater 50 is heated by the heater 70 so as to be supplied to the urea decomposition chamber P13 via the heated air delivery pipe P13, The temperature of the SCR reactor 20 is maintained at 250 ° C. or higher by introducing the heated air into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30, (20). At this time, the air flowing into the heater 70 flows in a heated state by the air heater 50, so that the amount of fuel consumed by the heater 70 required for regeneration of the SCR reactor 20 can be reduced.

3, the SCR system 300 for energy saving according to the third embodiment of the present invention includes a main engine 10, an SCR reactor 20, a mixer 30, a urea decomposition chamber 40 ), A burner 45 for decomposing urea, an air heater 50 and a blower 60.

The SCR system 300 according to the third embodiment of the present invention is provided with the heating air circulation pipe P15 at the rear end of the SCR reactor 20 as compared with the SCR system 100 of the first embodiment, The heating air discharged from the reactor 20 flows into the blower 60 and the heated air is introduced into the air heater 50 again by the blower 60 for circulation. Is the same as the SCR system 100 of the first embodiment illustrated in Fig.

In the SCR system 300 of the third embodiment, components having the same reference numerals as those of the SCR system 100 of the first embodiment similarly have the same functions and functions, so that the description thereof will be omitted for the convenience of explanation.

The control of the plurality of valves V13 to V22 for interrupting the entry and exit of the air and the exhaust gas into the air heater 50 is performed in the same manner as described above, so that the description thereof will be omitted.

The SCR system 300 supplies the air heated by the air heater 50 using waste heat of the exhaust gas to the SCR reactor 20 via the heated air delivery pipe P13, the urea decomposition chamber 40 and the mixer 30. [ The SCR reactor 20 is heated to apply the heated air flowing out of the SCR reactor 20 to the blower 60 through the heating air circulation pipe P15 and the blower 60 blows the heated air To the air heater (50) and circulates it. The SCR system 300 has a valve V28 for interrupting the flow of heated air from the SCR reactor 20 to the heated air circulation pipe P15 and the valve V28 is opened and closed under the control of the controller.

The SCR system 300 introduces the air heated by the air heater 50 into the SCR reactor 20 to heat the heated air used to heat the SCR reactor 20 through the heated air circulation pipe P15, So that the heat efficiency can be increased when the air heater 50 is heated by the air heater 50.

The SCR system 300 is operated in the SCR reactor 20 in a state of discharging the main engine exhaust gas through the bypass pipe P14 bypassing the SCR reactor 20 without purification treatment by the SCR reactor 20 on the outside of the ECA. And the main engine is stopped at the port to drive the view engine for starting the generator and the SCR reactor 20 is operated in a state of discharging the view engine exhaust gas through the view engine exhaust pipe P12 The air heated by the waste heat of the main engine or the exhaust gas of the view engine in the air heater 50 flows into the urea decomposition chamber 40 as it is through the heated air delivery pipe P13 The heated air is introduced into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30 so that the internal temperature of the SCR reactor 20 is maintained at 100 ° C or higher to heat the SCR reactor 20 It advances the ventilation operation. At this time, the heated air used for heating the SCR reactor 20 flows into the blower 60 from the SCR reactor 20 through the heated air circulation pipe P15 and circulates in the air heater 50. Therefore, Thereby increasing the thermal efficiency of the heat exchanger 50.

In addition, the SCR system 300 can be operated in a state where the main engine exhaust gas is not purified by the SCR reactor 20 on the pollution outside the ECA but is discharged through the bypass exhaust pipe P14 bypassing the SCR reactor 20, The air heated by the waste heat of the main engine exhaust gas is introduced into the urea decomposition chamber 40 through the heated air delivery pipe P13 in the air heater 50, The heated air introduced into the SCR reactor 20 is heated by the urea decomposing burner 45 and introduced into the SCR reactor 20 via the mixer 30 to raise the internal temperature of the SCR reactor 20 to 250 ° C or higher To regenerate the catalyst of the SCR reactor (20). At this time, the heated air used for heating the SCR reactor 20 flows into the blower 60 from the SCR reactor 20 through the heated air circulation pipe P15 and circulates in the air heater 50, The air heated by the burner 45 in the urea decomposition chamber 40 is introduced into the mixer 30 through the heated air delivery pipe P13 and then flows into the urea decomposition chamber 40. [ The air used for heating the SCR reactor 20 can be reused and the fuel consumption of the urea decomposition burner 45 required for the regeneration of the SCR reactor 20 can be reduced have.

The SCR system 400 for energy saving according to the fourth embodiment of the present invention includes a main engine 10, an SCR reactor 20, a mixer 30, a urea decomposition chamber 40 A burner 45 for decomposing urea, an air heater 50, a blower 60 and a heater 70.

The SCR system 400 according to the fourth embodiment of the present invention is provided with the heating air circulation pipe P15 at the rear end of the SCR reactor 20 as compared with the SCR system 200 of the second embodiment, The heating air discharged from the reactor 20 flows into the blower 60 and the heated air is introduced into the air heater 50 again by the blower 60 for circulation. Is the same as the SCR system 200 of the second embodiment illustrated in Fig.

In the SCR system 400 of the fourth embodiment, components having the same reference numerals as those of the SCR system 200 of the second embodiment similarly have the same functions and functions, and therefore, the description thereof will be omitted for the convenience of explanation.

The control of the plurality of valves V13 to V22 for interrupting the entry and exit of air and exhaust gas into the air heater 50 is performed in the SCR system 400 in the same manner as described above,

The SCR system 400 supplies the air heated by the air heater 50 using waste heat of the exhaust gas to the SCR reactor 20 via the heated air delivery pipe P13, the urea decomposition chamber 40 and the mixer 30. [ The SCR reactor 20 is heated to apply the heated air flowing out of the SCR reactor 20 to the blower 60 through the heating air circulation pipe P15 and the blower 60 blows the heated air The air heated by the air heater 50 is heated again by the exhaust gas waste heat and is applied to the heater 70 through the heated air delivery pipe P13. The SCR system 400 has a valve V28 for interrupting the flow of heated air from the SCR reactor 20 to the heated air circulation pipe P15 and the valve V28 is opened and closed under the control of the controller.

In this way, the SCR system 400 introduces the air heated by the air heater 50 into the SCR reactor 20, and blows the heated air used for heating the SCR reactor 20 through the heated air circulation pipe P15 to the blower 60 The air is introduced into the air heater 50 again by the blower 60 so as to be introduced into the heater 70 so that the thermal efficiency can be increased in heating the air by the air heater 50 and the heater 70 .

The SCR system 400 can be operated in the SCR reactor 20 in a state of discharging the main engine exhaust gas through the bypass pipe P14 bypassing the SCR reactor 20 without purification treatment by the SCR reactor 20 on the outside of the ECA. And the main engine is stopped at the port to drive the view engine for starting the generator and the SCR reactor 20 is operated in a state of discharging the view engine exhaust gas through the view engine exhaust pipe P12 The air heated by the waste heat of the main engine or the exhaust gas of the view engine in the air heater 50 flows into the urea decomposition chamber 40 as it is through the heated air delivery pipe P13 The heated air is introduced into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30 so that the internal temperature of the SCR reactor 20 is maintained at 100 ° C or higher to heat the SCR reactor 20 It advances the ventilation operation. At this time, the heated air used for heating the SCR reactor 20 flows into the blower 60 from the SCR reactor 20 through the heated air circulation pipe P15 and circulates in the air heater 50. Therefore, Thereby improving the thermal efficiency of the heat exchanger 50.

In addition, the SCR system 400 can be operated in a state where the main engine exhaust gas is not purified by the SCR reactor 20 on the pollution outside the ECA but is discharged through the bypass pipe P14 bypassing the SCR reactor 20, The air heated by the waste heat of the main engine exhaust gas in the air heater 50 is heated by the heater 70 so as to be supplied to the urea decomposition chamber P13 via the heated air delivery pipe P13, The temperature of the SCR reactor 20 is maintained at 250 ° C. or higher by introducing the heated air into the SCR reactor 20 via the urea decomposition chamber 40 and the mixer 30, (20). At this time, the heated air used for heating the SCR reactor 20 flows into the blower 60 from the SCR reactor 20 through the heated air circulation pipe P15 and circulates in the air heater 50, Since the gas is heated by the waste heat of the gas and then supplied to the heater 70, the fuel consumption of the heater 70 required for regeneration of the SCR reactor 20 can be reduced.

As described above, according to the present invention, the air heated by the exhaust gas waste heat of the main engine or the view engine is introduced into the SCR reactor 20 to remove the contamination of the SCR reactor catalyst to regenerate the catalyst or to heat the SCR reactor 20 And the ventilation is progressed, it is possible to prevent poisoning of the SCR reactor at the time of catalyst regeneration, heating and ventilation operation, and to save energy consumption, which is very economical.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. And such changes are considered to be within the technical scope of the present invention.

The present invention can be applied to a case where the engine exhaust gas is purified from a ship. According to the present invention, as the exhaust gas purifying treatment for removing nitrogen oxides of the engine exhaust gas is performed by the SCR reactor, contamination of the SCR reactor catalyst due to the ammonium di-sulphate generated in the SCR reactor is removed, The air heated by the exhaust gas waste heat of the main engine or the view engine is introduced into the SCR reactor so that the contamination of the SCR reactor catalyst can be prevented The catalyst is regenerated or the SCR reactor is heated and ventilated. Therefore, poisoning of the SCR reactor is prevented during regeneration of catalyst, heating and ventilation operation, and energy consumption is reduced.

10; A main engine 20; SCR reactor
30; Mixer 40; Urea decomposition chamber
45; A burner 50 for urea decomposition; Air heater
60; Blower 70; Heater
100, 200, 300, 400; SCR systems V11 to V22, V25, V26; valve
P11; Main Engine Exhaust P12; View engine exhaust
P13; Heated air delivery pipe P15; Heated air circulation piping

Claims (9)

SCR reactor SCR system for regenerating catalyst by removing pollution of catalyst or for saving energy in case of heating and ventilation to SCR reactor,
A blower for introducing air,
An air heater that heats the air introduced from the blower by the exhaust gas waste heat of the main engine or the view engine,
And a heated air delivery pipe for introducing the air heated by the air heater into the urea decomposition chamber;
The heated air flowing into the urea decomposition chamber through the heated air delivery pipe is introduced into the SCR reactor via the mixer,
Wherein the main engine exhaust gas and the view engine exhaust gas used for heating the air in the air heater are discharged through respective exhaust gas discharge pipes.
The method according to claim 1,
And the heated air introduced into the urea decomposition chamber through the heated air delivery pipe is heated by a burner for urea decomposition.
The method according to claim 1,
Further comprising a heater for heating the heated air flowing into the urea decomposition chamber through the heated air delivery pipe by using energy.
4. The method according to any one of claims 1 to 3,
A view engine exhaust gas inlet member for allowing and exhausting the view engine exhaust gas to and from the air heater,
A main engine exhaust gas entrance member for allowing the main engine exhaust gas to flow into and out of the air heater,
Further comprising an air inlet member for allowing air to flow into and out of the air heater.
SCR reactor SCR system for regenerating catalyst by removing pollution of catalyst or for saving energy in case of heating and ventilation to SCR reactor,
A heating air circulation pipe installed at the rear end of the SCR reactor for circulating heated air discharged from the SCR reactor,
A blower for introducing the air supplied through the heated air circulation pipe into the air heater,
An air heater that heats the air introduced from the blower by the exhaust gas waste heat of the main engine or the view engine,
And a heated air delivery pipe for introducing the air heated by the air heater into the urea decomposition chamber;
The heated air flowing into the urea decomposition chamber through the heated air delivery pipe is introduced into the SCR reactor via the mixer,
Wherein the main engine exhaust gas and the view engine exhaust gas used for heating the air in the air heater are discharged through respective exhaust gas discharge pipes.
6. The method of claim 5,
And the heated air introduced into the urea decomposition chamber through the heated air delivery pipe is heated by a burner for urea decomposition.
6. The method of claim 5,
Further comprising a heater for heating the heated air flowing into the urea decomposition chamber through the heated air delivery pipe by using energy.
6. The method of claim 5,
Further comprising a valve for interrupting the flow of heated air from the SCR reactor to the heated air circulation pipe.
9. The method according to any one of claims 5 to 8,
A view engine exhaust gas inlet member for allowing and exhausting the view engine exhaust gas to and from the air heater,
A main engine exhaust gas entrance member for allowing the main engine exhaust gas to flow into and out of the air heater,
Further comprising an air inlet member for allowing air to flow into and out of the air heater.

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