KR102651903B1 - Exhaust Gas Heat Recovery System And Method For Ship - Google Patents

Abstract

A method and system for recovering exhaust waste heat from a ship are provided. The method of recovering exhaust waste heat from a ship of the present invention includes the steps of: 1) selectively supplying high-sulfur oil and low-sulfur oil as fuel for a ship engine; 2) a waste heat recovery unit heating water using the exhaust discharged from the engine as a heat source to produce steam and supplying it to steam consumers within the ship; and 3) condensing the steam discharged from the steam consumer and circulating it to step 2); Including, the waste heat recovery unit is dual-set to operate in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine, and a pump that pumps water from the waste heat recovery unit according to the steam pressure. It is characterized in that the head pressure of is adjusted.

Description

Exhaust waste heat recovery system and method for ship {Exhaust Gas Heat Recovery System And Method For Ship}

The present invention relates to a ship's exhaust waste heat recovery system and method, and more specifically, to produce steam using the exhaust discharged from the ship's engine as a heat source and supply it to the steam consumer on board, where high-sulfur oil or low-sulfur oil is supplied to the engine. It relates to a ship's exhaust waste heat recovery system and method that adjusts the amount of waste heat recovery by dual setting it to operate in high-pressure or low-pressure steam mode depending on the supply mode.

Recently, when burning heavy oil, MDO (Marine Diesel Oil), etc., which are conventionally used as fuel for various engines on ships, the seriousness of environmental pollution due to various harmful substances contained in the exhaust gas has emerged, so oils such as heavy oil are used as fuel. Regulations on various engines used on ships are being strengthened.

In general, among the exhaust gas components emitted from ships, nitrogen oxides (NOx) and sulfur oxides (SOx) are regulated by the International Maritime Organization (IMO) under the UN, the European Union (EU), and California (CARB). Each agency and organization, including the Air Resources Board, also places limits on sulfur oxide (SOx) emissions. The Protocol to the Prevention of Marine Pollution (MARPOL 1973/1978; The Prevention of Marine Pollution from Ships), written in 1973 and revised and supplemented in 1978, is also in effect.

Vessels operating within sulfur oxide emission control areas stipulated by some agencies and organizations are required to use low sulfur fuel oil (Low Sulfur Marine Gas Oil) with a sulfur content of up to 0.1% depending on the application period, and takes effect in 2020. In the IMO's ship sulfur oxide emission regulations (Global Sulfur Cap 2020), the sulfur oxide content standard for ship fuel will be strengthened from the existing 3.5% to 0.5%.

Vessels scheduled to sail in sulfur oxide emission control areas are equipped with low-sulfur oil fuel tanks to store low-sulfur oil and heavy oil bunk tanks to store heavy oil, and when sailing in sulfur oxide emission control areas, low-sulfur oil is used and controlled. Outside the region, high-sulfur oil such as heavy oil is used.

SO ₂ contained in exhaust gas condenses into sulfuric acid (H ₂ SO ₄ ), causing sulfuric acid dew point corrosion, which corrodes metals. When installing a heat exchanger using exhaust gas waste heat, the device's When the metal surface temperature easily falls below the dew point, corrosion can occur significantly, which is called low-temperature corrosion. When low-sulfur oil is used, the sulfur content in the exhaust gas emitted from the engine is lowered, lowering the possibility of low-temperature corrosion, and high-sulfur oil has a high possibility of low-temperature corrosion.

Meanwhile, there are many devices on board that require a heat source supply, and steam can be supplied to these devices to supply a heat source.

The present invention seeks to provide a waste heat recovery system that can recover exhaust gas waste heat in accordance with the conditions of use of high-sulfur oil and low-sulfur oil in ships and maximize the supply of steam required within the ship.

According to one aspect of the present invention for solving the above-described problem,

1) Selectively supplying high-sulfur oil and low-sulfur oil as fuel for ship engines;

2) a waste heat recovery unit heating water using the exhaust discharged from the engine as a heat source to produce steam and supplying it to steam consumers within the ship; and

3) condensing the steam discharged from the steam consumer and circulating it to step 2); Including,

The waste heat recovery unit is dual-set to operate in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine, and the head pressure of the pump that pumps water from the waste heat recovery unit is adjusted according to the steam pressure. A method for recovering exhaust waste heat from a ship is provided, which is characterized in that it is controlled.

Preferably, the waste heat recovery unit includes an auxiliary boiler unit that receives water and heats it; an economizer that receives heated water from the auxiliary boiler unit and additionally heats it using exhaust waste heat from the engine; a circulation pump that supplies water from the auxiliary boiler unit to the economizer; and a throttling valve provided in a pipe through which water is supplied from the circulation pump to the economizer, wherein water additionally heated with exhaust waste heat from the economizer is supplied to a steam drum provided in the auxiliary boiler unit. You can.

Preferably, when low-sulfur oil is supplied to the engine, the waste heat recovery unit is operated in a low-pressure steam mode, so that the head front pressure of the steam drum and the circulation pump is operated at low pressure, and the heat flowing into the economizer by the throttling valve is operated at low pressure. As the flow rate of water increases, the amount of exhaust waste heat recovered from the economizer can be increased.

Preferably, when high-sulfur oil is supplied to the engine, the waste heat recovery unit is operated in a high-pressure steam mode, so that the head front pressure of the steam drum and the circulation pump is operated at high pressure, and the heat flowing into the economizer by the throttling valve is operated at high pressure. As the flow rate of water decreases, the amount of exhaust waste heat recovered from the economizer may be reduced.

Preferably, an engine provided on a ship and capable of selectively receiving high-sulfur oil and low-sulfur oil as fuel; a waste heat recovery unit that produces steam using exhaust discharged from the engine as a heat source and supplies it to steam consumers within the ship; A steam circulation line through which the steam is circulated through the waste heat recovery unit and the steam consumer; and a condenser provided in the steam circulation line to condense the steam discharged after use from the steam consumer, wherein the engine is operated in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine. A ship's exhaust waste heat recovery system is provided, wherein the waste heat recovery unit is dual-set, and the head pressure of the pump that pumps water from the waste heat recovery unit is adjusted according to the steam pressure.

Preferably, the waste heat recovery unit includes an auxiliary boiler unit that receives water and heats it; an economizer that receives heated water from the auxiliary boiler unit and additionally heats it using exhaust waste heat from the engine; a circulation pump that supplies water from the auxiliary boiler unit to the economizer; and a throttling valve provided in a pipe through which water is supplied from the circulation pump to the economizer, wherein water additionally heated with exhaust waste heat from the economizer is supplied to a steam drum provided in the auxiliary boiler unit. You can.

Preferably, when low-sulfur oil is supplied to the engine, the waste heat recovery unit is operated in a low-pressure steam mode, so that the head front pressure of the steam drum and the circulation pump is operated at a low pressure, and is introduced into the economizer by the throttling valve. The flow rate of water increases, increasing the amount of exhaust waste heat recovered from the economizer, and when high-sulfur oil is supplied to the engine, the waste heat recovery unit operates in high-pressure steam mode, and the head shear pressure of the steam drum and the circulation pump is It is operated at high pressure, and the flow rate of water flowing into the economizer is reduced by the throttling valve, thereby reducing the amount of exhaust waste heat recovered from the economizer.

Preferably, a dump line branches off from the steam circulation line downstream of the waste heat recovery unit, bypasses the steam consumer, and connects to the condenser; A steam dump valve provided in the dump line; a cascade tank provided in the steam circulation line to which water condensed in the condenser is supplied; and a supply pump provided in the steam circulation line and supplying water from the cascade tank to the waste heat recovery unit. It further includes, and the steam dump valve and steam drum may be dual-set to operate in high-pressure or low-pressure mode, respectively, depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine.

Preferably, a fuel supply line through which fuel of high-sulfur oil and low-sulfur oil is supplied to the engine; HSFO line through which the high sulfur oil is supplied to the fuel supply line; An LSFO line through which the low-sulfur oil is supplied to the fuel supply line; a three-way valve provided at a point where the HSFO line and the LSFO line are connected to the fuel supply line to open and close the HSFO line and the LSFO line; and a fuel supply unit provided upstream of the engine to heat the high-sulfur oil or low-sulfur oil to be supplied to the engine, and steam generated in the waste heat recovery unit may be supplied to the fuel supply unit.

In the waste heat recovery system and method of the present invention, the waste heat recovery unit is dual-set to operate in high-pressure or low-pressure steam mode according to the fuel supply of high-sulfur oil and low-sulfur oil to the onboard engine, thereby maximizing exhaust gas waste heat according to fuel supply conditions. can be recovered to generate steam and supply it to consumers on board, and low-temperature corrosion of the device can be prevented.

In addition, by recovering exhaust gas waste heat to generate steam and securing the steam needed for steam consumers on board, fuel consumption for operating other devices for steam generation, such as auxiliary boilers, can be reduced, increasing the ship's energy efficiency and ship operating costs. can save.

Figure 1 schematically shows a system to which a ship's exhaust waste heat recovery method is applied according to an embodiment of the present invention.

In order to fully understand the operational advantages of the present invention and the objectives achieved by practicing the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the structure and operation of a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. Here, in adding reference numerals to components in each drawing, it should be noted that identical components are indicated with the same reference numerals as much as possible, even if they are shown in different drawings.

In the embodiments of the present invention described later, ships are installed with engines that can use fuel oil such as low-sulfur oil and high-sulfur oil alone as fuel for propulsion engines or fuel for power generation engines, or can be used together with other fuels such as LNG. It can be any type of ship equipped with engines that use fuel oil. Representative examples include ships with self-propelled capabilities such as LPG carriers, LNG carriers, liquid hydrogen carriers, and LNG RVs (Regasification Vessels), as well as LNG FPSOs (Floating Production Storage Offloading) and LNG FSRUs (Floating Storage Regasification Units). Marine structures that do not have propulsion capabilities but are floating in the sea may also be included.

Figure 1 schematically shows a system according to a method of recovering exhaust waste heat from a ship according to an embodiment of the present invention.

In the system of this embodiment, 1) selectively supplying high-sulfur oil and low-sulfur oil as fuel for a ship engine; 2) a step of heating water in the waste heat recovery unit using the exhaust discharged from the engine as a heat source to produce steam and supplying it to steam consumers within the ship; and 3) condensing the steam discharged from the steam consumer and circulating it in step 2) to recover the exhaust waste heat and produce steam.

In particular, this embodiment is characterized by dual setting the waste heat recovery unit to operate in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine. Devices such as the dual-set waste heat recovery unit can operate automatically or manually in high-pressure or low-pressure steam mode depending on the fuel supply mode of high-sulfur oil or low-sulfur oil.

As shown in FIG. 1, the system of this embodiment includes an engine (E) that is provided on a ship and can selectively receive high-sulfur oil and low-sulfur oil as fuel, and produces steam using the exhaust discharged from the engine as a heat source to generate steam within the ship. A steam circulation line (SL) is provided in which steam is circulated through the waste heat recovery unit (100), the waste heat recovery unit, and the steam consumer (200) supplied to the consumer. In the steam circulation line, the steam discharged after use at the steam consumer is condensed. Devices such as a condenser 300, a cascade tank 400 to which water condensed in the condenser is supplied, and a supply pump 500 that supplies water from the cascade tank to the waste heat recovery unit and circulates it are provided.

The waste heat recovery unit 100 includes an auxiliary boiler unit 110 that receives water supplied from the supply pump and heats it, an economizer 120 that receives heated water from the auxiliary boiler unit and further heats it with the exhaust waste heat of the engine, and an auxiliary boiler unit 110 that receives water supplied from the supply pump and heats it. Devices such as a circulation pump 130 that supplies water from the boiler unit to the economizer and a throttling valve 140 provided in a pipe that supplies water from the circulation pump to the economizer may be configured. Water additionally heated with exhaust waste heat from the economizer may be supplied to a steam drum (not shown) provided in the auxiliary boiler unit 110. The circulation pump 130 may be installed as a centrifugal pump, and the throttling valve 140 may adjust the flow rate by changing the cross-sectional area of the pipe to provide resistance to the pipe.

In this embodiment, an economizer is installed in the waste heat recovery unit to recover exhaust waste heat, and since a separate steam drum is not installed in the economizer, the steam drum of the auxiliary boiler unit is used. Water circulates along the circulation line (CL) connected to the auxiliary boiler unit from the auxiliary boiler unit 110 through the circulation pump 130 and economizer 120, and is used by the circulation pump 130 and the throttling valve 140. The flow rate and flow rate of water supplied to the economizer can be adjusted.

Meanwhile, a fuel supply line (FL) for supplying high-sulfur oil and low-sulfur oil fuel to the engine is connected to the engine, and upstream of the fuel supply line is a HSFO line (HSL) for supplying high-sulfur oil to the fuel supply line and a low-sulfur fuel supply line. The LSFO line (LSL) through which oil is supplied is connected. At the point where the HSFO line and LSFO line are connected to the fuel supply line, a three-way valve (TV) is provided to open and close the HSFO line and LSFO line. Depending on the opening and closing of the three-way valve, high-sulfur oil or low-sulfur oil is supplied to the engine through the fuel supply line. Oil is supplied.

A dump line (DL) is branched from the steam circulation line to the rear end of the waste heat recovery unit, bypassing the steam consumer and connected to the condenser, and a steam dump valve (DV) is provided on the dump line to open and close the dump line. The waste heat recovery unit 100 is provided with a steam drum (not shown) to accommodate steam produced from exhaust waste heat as a heat source and supplied to steam consumers. The steam dump valve and steam drum are dual-set to operate in high-pressure or low-pressure mode, respectively, depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine.

High-sulfur oil has a higher viscosity than low-sulfur oil. Fuel oil is usually heated and supplied to the engine at the required viscosity, and heating of fuel oil can be done with steam.

For this purpose, in this embodiment, a fuel supply unit (not shown) may be additionally provided upstream of the engine to heat high-sulfur oil or low-sulfur oil to be supplied to the engine, and steam generated in the waste heat recovery unit may be provided as a heat source for heating fuel oil. It can be supplied to the fuel supply section.

In particular, low-sulfur oil with low viscosity has a lower fuel heating temperature than high-sulfur oil, so supplying low-sulfur oil with low viscosity as engine fuel can lower the temperature of the steam required for heating fuel oil. In addition, when low-sulfur oil is supplied as engine fuel, the sulfur content in the exhaust gas is lowered, lowering the possibility of low-temperature corrosion occurring, and thus the temperature limit during exhaust gas heat recovery is relaxed.

Therefore, in this embodiment, taking this into consideration, the steam pressure settings of devices such as steam dump valves and steam drums are dual-set to operate in high-pressure or low-pressure mode, respectively, depending on the fuel supply mode of high-sulfur oil or low-sulfur oil of the engine, so that waste heat recovery is achieved. Adjust the quantity and produce as much steam as possible depending on fuel conditions.

Specifically, in the engine's LSFO (Low Sulfur Fuel Oil) mode, the LSFO line (LSL) is opened with a three-way valve (TV), low-sulfur oil is supplied to the engine through the fuel supply line (FL), and the steam system operates at low pressure. mode to operate both the steam drum and steam dump valve in low pressure mode. In the low-pressure mode in which low-sulfur oil is supplied, the waste heat recovery unit 100 is also operated in low-pressure steam mode and the head shear pressure of the circulation pump 130, which pumps water to the economizer through the circulation line, is also operated at low pressure, and the throttling valve As the flow rate of water flowing into the economizer 120 through 140 increases, the amount of waste heat recovered from the exhaust increases, and more steam can be produced from the exhaust.

In the engine's HSFO (High Sulfur Fuel Oil) mode, the HSFO line (HSL) is opened with a three-way valve (TV) to supply high sulfur oil to the engine through the fuel supply line (FL). At this time, the steam system is operated in high pressure mode, so that both the steam drum and steam dump valve are operated in high pressure mode. The waste heat recovery unit also operates in high-pressure steam mode, and the head shear pressure of the circulation pump also operates at high pressure. At this time, the flow rate of water flowing from the circulation pump through the circulation line and through the throttling valve to the economizer decreases, thereby reducing the amount of exhaust waste heat recovered from the economizer and reducing steam production by exhaust waste heat. If steam production is insufficient due to low exhaust waste heat recovery, steam production in the auxiliary boiler unit 110 can be increased and supplied to consumers within the ship.

In this embodiment, the engine provided on the ship may be an engine supplied only with high-sulfur oil and low-sulfur fuel oil, or it may be a DF (Dual Fuel) engine supplied with fuel oil and LNG as fuel. When this embodiment is applied to a ship equipped with a DF engine, the amount of steam generated in the waste heat recovery unit can be adjusted by adjusting the steam system pressure in Fuel Gas mode.

As described above, by dual setting the pressure of the steam system according to the fuel supply mode according to the method of this embodiment, the amount of waste heat recovery and steam generation is secured to the maximum according to the fuel supply conditions, and the operation of auxiliary boilers, etc. is reduced to use separate energy. can be reduced. In addition, the installed capacity of the steam production system can be reduced through efficient exhaust waste heat recovery and steam production control, thereby reducing CAPEX and OPEX.

It is obvious to those skilled in the art that the present invention is not limited to the above-mentioned embodiments, and that it can be implemented with various modifications or variations without departing from the technical gist of the present invention. It was done.

E: engine
100: Waste heat recovery unit
110: Auxiliary boiler unit
120: Economizer
130: Circulation pump
140: Throttling valve
200: Steam consumer
300: Condenser
400: Cascade tank
500: Supply pump
SL: Steam circulation line
DL: dump line
FL: Fuel supply line
HSL: HSFO line
LSL: LSFO line
DV: Steam dump valve
TV: three-way valve

Claims (9)

1) Selectively supplying high-sulfur oil and low-sulfur oil as fuel for ship engines;
2) a waste heat recovery unit heating water using the exhaust discharged from the engine as a heat source to produce steam and supplying it to steam consumers within the ship; and
3) condensing the steam discharged from the steam consumer and circulating it to step 2); Including,
The waste heat recovery unit is dual-set to operate in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine, and the head pressure of the pump that pumps water from the waste heat recovery unit is adjusted according to the steam pressure. regulated,
The waste heat recovery unit includes an auxiliary boiler unit that receives water and heats it; an economizer that receives heated water from the auxiliary boiler unit and additionally heats it using exhaust waste heat from the engine; and a circulation pump that supplies water from the auxiliary boiler unit to the economizer, wherein water additionally heated with exhaust waste heat from the economizer is supplied to a steam drum provided in the auxiliary boiler unit. Waste heat recovery method. The method of claim 1, wherein the waste heat recovery unit,
A throttling valve provided in a pipe through which water is supplied from the circulation pump to the economizer. According to clause 2,
When low-sulfur oil is supplied to the engine, the waste heat recovery unit operates in low-pressure steam mode,
The head front pressure of the steam drum and the circulation pump is operated at low pressure, and the flow rate of water flowing into the economizer by the throttling valve increases, thereby increasing the amount of exhaust waste heat recovered from the economizer. Exhaust waste heat recovery method. According to clause 2,
When high-sulfur oil is supplied to the engine, the waste heat recovery unit operates in high-pressure steam mode,
The head front pressure of the steam drum and the circulation pump is operated at high pressure, and the flow rate of water flowing into the economizer is reduced by the throttling valve, thereby reducing the amount of exhaust waste heat recovered from the economizer. Exhaust waste heat recovery method. An engine installed on a ship that can selectively receive high-sulfur oil and low-sulfur oil as fuel;
It includes an auxiliary boiler unit that receives and heats water, an economizer that receives heated water from the auxiliary boiler unit and additionally heats it with exhaust waste heat from the engine, and a circulation pump that supplies water from the auxiliary boiler unit to the economizer. Thus, a waste heat recovery unit that produces steam using the exhaust discharged from the engine as a heat source and supplies it to steam consumers in the ship;
A steam circulation line through which the steam is circulated through the waste heat recovery unit and the steam consumer; and
A condenser provided in the steam circulation line to condense the steam discharged from the steam consumer after use,
Water additionally heated with exhaust waste heat from the economizer is supplied to a steam drum provided in the auxiliary boiler unit,
The waste heat recovery unit is dual-set to operate in high-pressure or low-pressure steam mode depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine, and the head pressure of the pump that pumps water from the waste heat recovery unit is adjusted according to the steam pressure. A ship's exhaust waste heat recovery system, characterized in that it is regulated. The method of claim 5, wherein the waste heat recovery unit,
A throttling valve provided in a pipe through which water is supplied from the circulation pump to the economizer. According to clause 6,
When low-sulfur oil is supplied to the engine, the waste heat recovery unit operates in a low-pressure steam mode, so that the head front pressure of the steam drum and the circulation pump is operated at low pressure, and the flow rate of water flowing into the economizer by the throttling valve is increases, the amount of exhaust waste heat recovered from the economizer increases,
When high-sulfur oil is supplied to the engine, the waste heat recovery unit is operated in high-pressure steam mode, the head front pressure of the steam drum and the circulation pump is operated at high pressure, and the flow rate of water flowing into the economizer by the throttling valve is adjusted to A ship's exhaust waste heat recovery system, characterized in that the amount of exhaust waste heat recovered from the economizer is reduced. According to clause 6,
a dump line branching from the steam circulation line downstream of the waste heat recovery unit, bypassing the steam consumer, and connected to the condenser;
A steam dump valve provided in the dump line;
a cascade tank provided in the steam circulation line to which water condensed in the condenser is supplied; and
a supply pump provided in the steam circulation line and supplying water from the cascade tank to the waste heat recovery unit; It further includes,
The steam dump valve and steam drum are dual-set to operate in high-pressure or low-pressure mode, respectively, depending on the fuel supply mode in which high-sulfur oil or low-sulfur oil is supplied to the engine. According to clause 5,
A fuel supply line through which fuel of high-sulfur oil and low-sulfur oil is supplied to the engine;
HSFO line through which the high sulfur oil is supplied to the fuel supply line;
An LSFO line through which the low-sulfur oil is supplied to the fuel supply line;
a three-way valve provided at a point where the HSFO line and the LSFO line are connected to the fuel supply line to open and close the HSFO line and the LSFO line; and
It further includes a fuel supply unit provided upstream of the engine to heat the high-sulfur oil or low-sulfur oil to be supplied to the engine.
A ship's exhaust waste heat recovery system, characterized in that steam generated in the waste heat recovery unit can be supplied to the fuel supply unit.

Images