KR100888394B1 - Optimization method for install more ??? vaporization system - Google Patents

Abstract

In the present invention, when expanding the gasification facilities at each natural gas production base, ORV system and SMV at the minimum cost in consideration of the amount of natural gas to be produced at each time in each natural gas production base, operation cost, maintenance cost and depreciation cost, etc. The present invention relates to a method for optimizing the expansion of an LNG vaporization system that can optimize the expansion ratio of the system.

Natural gas, vaporization system

Description

Optimization method for expansion of LN vaporization system {Optimization method for install more LN vapor vaporization system}

The present invention relates to a method for optimizing the expansion of the LNG vaporization system, in particular, when expanding the gasification facilities in each natural gas production base, the amount of natural gas to be produced at each natural gas production base at each time zone, operation costs, maintenance costs and depreciation The present invention relates to a method for optimizing the expansion of an LNG vaporization system that can optimize the expansion ratio of an ORV system and an SMV system in consideration of an amortization cost.

Conventional liquefied natural gas (hereinafter referred to as LNG) vaporization systems include an open rack vaporizer (ORV) system and a submerged vaporizer (SMV) system.

The ORV system uses seawater heat to vaporize LNG at -160 ° C with natural gas at 0 ° C. This ORV system has the advantage of low operating costs by using seawater heat to vaporize LNG. However, the ORV system requires a number of auxiliary facilities for using seawater, such as a pump for pumping seawater, a water intake for seawater, and a filter for filtering seawater as seawater is used to vaporize LNG. Accordingly, ORV system has a disadvantage that the initial installation cost is expensive. In addition, the ORV system has a problem that LNG vaporization efficiency is lowered when the temperature of the sea water is lowered, and LNG is not vaporized when the temperature of the sea water is lowered below 5 ° C. ORV system is equipped with See Water Heater (SWH) in order to increase the low seawater temperature in winter, which raises the seawater temperature by 2 ° C and supplies it to the ORV system. Therefore, even if the ORV system is provided with SWH, the ORV system does not significantly increase the vaporization efficiency, and there is a problem in that LNG cannot still be vaporized when the seawater temperature is lowered below 3 ° C.

The SMV system uses the gas burned heat to vaporize LNG at -160 ° C into natural gas at 0 ° C. The SMV system vaporizes LNG with natural gas by applying heat obtained by burning gas directly to LNG at -160 ° C, thus eliminating the need for additional equipment such as an ORV system. Therefore, SMV system has the advantage of low initial installation cost. However, the SMV system has a disadvantage in that operating cost is high by directly obtaining the heat required to vaporize LNG at -160 ° C into natural gas at 0 ° C.

Therefore, the current natural gas production base has a low average seawater temperature. For example, Incheon natural gas production base has an ORV system and an SMV system in a ratio of 4: 6, and vaporizes LNG by using an ORV system and an SMV system together. For example, Tongyeong Natural Gas Production Base has a ratio of 8: 2 for ORV system and SMV system, and vaporizes LNG by using ORV system and SMV system. For example, the Pyeongtaek Natural Gas Production Base has an 6: 4 ratio between the ORV system and the SMV system, and vaporizes the LNG using the ORV system and the SMV system together. In addition, the natural gas production bases are also expanding the natural gas vaporization system on the basis of the time considering the above ratio and requirements.

However, it is inefficient for each natural gas production base to determine the installation rate of ORV system and SMV system in each natural gas production base considering only the average seawater temperature of each natural gas production base, and to increase the gasification system according to the ratio. to be. If the ratio of installation of ORV system and SMV system is decided by considering only the average seawater temperature, for example, in case of Incheon natural gas production base, if the seawater temperature is extremely lower than 0 ℃ in winter, if only SMV system is added, It will be possible to produce the natural gas required, but there may be a problem in using the SMV system to produce the natural gas needed even in summer when the sea water temperature is high.

Therefore, the operation cost, maintenance cost, and depreciation cost must be considered in determining the installation rate and the expansion rate of the ORV system and the SMV system in each natural gas production base to be efficient in the installation cost and the operating cost.

Accordingly, an object of the present invention is to minimize the cost in consideration of the amount of natural gas to be produced at each natural gas production base at each time zone, operation and maintenance costs, depreciation cost, etc. It is to provide an expansion optimization method for LNG vaporization system that can optimize the expansion ratio of ORV system and SMV system.

In order to achieve the above object, the expansion optimization method of the LNG vaporization system according to an embodiment of the present invention comprises the steps of inputting the total natural gas production to be produced in the next year in the natural gas production base to expand the LNG vaporization system; ; Inputting a delivery pattern of natural gas for each year of the past year of the natural gas production base; Calculating the amount of natural gas output per year of the following year of the natural gas production base; Inputting seawater temperature for each year of the past year of the natural gas production base; Calculating an efficiency of an annual time zone ORV system of the natural gas production base according to the seawater temperature of the natural gas production base in the past year; Calculating the NG production capacity of the natural gas production base at each time zone; Setting and inputting a case for a ratio of the ORV system and the SMV system to vaporize LNG; Calculating the necessary radix of the ORV system, the SMV system, and the SWH by the set time of the next year according to the set case according to the amount of natural gas discharged by the yearly time zone of the following year; Inputting operating costs of the ORV system, the SMV system, and the SWH; Calculating and storing operating costs of the ORV system, the SMV system, and the SWH according to the following yearly time zones; Calculating operating costs of the ORV system, the SMV system, and the SWH for each case of the ORV system and the SMV system according to the following yearly time zone; And selecting a case of a minimum operating cost among the operating costs of the ORV system, the SMV system, and the SWH for each of the stored next yearly time zones.

The natural gas delivery pattern for each year of the past year of the natural gas production base is calculated by dividing the natural gas delivery amount per year for the past year by the total time of the natural gas production base.

The amount of natural gas output per year of the following year of the natural gas production base is calculated by multiplying the total natural gas production amount to be produced in the following year by the pattern of delivery of natural gas per year of the past year.

The annual time zone NG production capacity of the natural gas production base is the efficiency of the annual time zone ORV system according to the sea water temperature × vaporization capacity of the ORV system + capacity of the annual time zone SMV system + annual time zone SWH capacity.

The case for the ratio of the ORV system and the SMV system to vaporize the LNG, reduces the ratio of the ORV system by 10% from 100% to 0% by 10%, the ratio of the SMV system by 10% from 0% to 100 Choose by increasing.

The operating costs of the ORV system, the SMV system and the SWH by the annual time zone are required base of the ORV system by the annual time zone × operating cost of the ORV system + required base of the SMV system by the annual time zone × SMV system The operating cost of + the required radix of the SWH × operating cost of the SMV system.

The operating costs of the ORV system, the SMV system, and the SWH include operation costs, maintenance costs, and depreciation costs of the ORV system, the SMV system, and the SWH.

The expansion optimization method of the LNG vaporization system comprises the steps of inputting the current state of the current gasification system of the natural gas production base; And expanding the ORV system or expanding the SMV system so as to fit the case of the minimum operation cost selected from the current gasification system status of the natural gas production base.

As described above, in the expansion optimization method of the LNG vaporization system according to an embodiment of the present invention, when the gasification facility is added to the natural gas production base, the amount of natural gas to be produced at the natural gas production base by the time zone of the year after year Considering the expansion ratio of ORV system and SMV system, efficiency of expansion of LNG vaporization system can be improved.

In addition, the optimization method for the expansion of the LNG vaporization system according to an embodiment of the present invention in consideration of the operating and maintenance costs, depreciation costs and ORV system and SMV system of the ORV system and SMV system when expanding the gasification facility in the natural gas production base, etc. By selecting the rate of expansion of the system, it is possible to improve the efficiency of the expansion of the LNG vaporization system in terms of cost.

Hereinafter, a preferred embodiment of the present invention will be described with reference to FIG. 1.

1 is a flowchart illustrating a method for optimizing the expansion of an LNG vaporization system according to an embodiment of the present invention.

Referring to Figure 1, the expansion optimization method of the LNG vaporization system according to an embodiment of the present invention inputs the current state of the current vaporization system of the natural gas production base (hereinafter, natural gas production base) to expand the LNG vaporization system ( S10). The current gasification system of natural gas production bases is based on the ORV system headings, SMV system headings and SWH headings currently installed in natural gas production bases, ORV systems installed in natural gas production bases, vaporization capacity of SMV systems, And the capacity of the SWH.

And, the expansion optimization method of the LNG vaporization system of the present invention inputs the total natural gas production to be produced in the natural gas production base in the next year (S20).

On the other hand, the expansion optimization method of the LNG vaporization system of the present invention calculates and stores the delivery pattern of natural gas for each year of the past year of the natural gas production base. The natural gas outflow pattern of the natural gas production base by year in the past year is calculated by dividing the natural gas outflow in natural gas production base by the past year in the past year.

In the expansion optimization method of the LNG vaporization system of the present invention inputs the natural gas discharge pattern of the year-to-year time zone of the natural gas production base is calculated and stored (S25).

Then, the expansion optimization method of the LNG vaporization system of the present invention is to produce natural gas by multiplying the total natural gas production to be produced at the natural gas production base the next year multiplied by the pattern of natural gas by the year of the past year Calculate the amount of natural gas discharged by the time zone of the base the following year (S30).

On the other hand, the expansion optimization method of the LNG vaporization system of the present invention stores the sea water temperature for each year of the past year of the natural gas production base.

In the expansion optimization method of the LNG vaporization system of the present invention inputs seawater temperature for each year of the past year of the stored natural gas production base (S35).

Then, the expansion optimization method of the LNG vaporization system of the present invention calculates the efficiency of the ORV system for each time zone by using the seawater temperature of the yearly time zone of the natural gas production base (S40), the annual time of the natural gas production base Calculate the NG production capacity per unit (S50). The annual NG production capacity of the natural gas production base is the efficiency of the annual time zone ORV system according to the sea temperature × the vaporization capacity of the ORV system + the vaporization capacity of the SMV system for each time zone + the SWH capacity for each time zone.

Subsequently, the expansion optimization method of the LNG vaporization system of the present invention sets and inputs a case for the ratio of the ORV system and the SMV system to vaporize the LNG (S60). For example, 100% of the LNG will be ORV system, and 0% of LNG will be vaporized by SMV system, that is, the ratio of ORV system and SMV system to vaporize LNG is set to 10: 0, 90% of LNG is ORV 10% of LNG will be vaporized by SMV system, that is, the ratio of ORV system and SMV system to vaporize LNG is set to 9: 1, 80% of LNG is ORV system and 20% of LNG is SMV system. Set and input the case about whether to vaporize, ie, set the ratio of the ORV system and SMV system to vaporize LNG to 8: 2.

Then, the expansion optimization method of the LNG vaporization system of the present invention calculates the required base of the yearly time zone ORV system, SMV system and SWH according to the case set in step S60 according to the yearly time zone natural gas discharge amount of the following year (S70).

In addition, the expansion optimization method of the LNG vaporization system of the present invention by inputting the operating costs of the ORV system, SMV system and SWH (S75), according to the annual time zone according to the required base of the ORV system, SMV system and SWH calculated in step S70 The operation cost of the ORV system, SMV system, and SWH is calculated and stored (S80). Operating costs of ORV system, SMV system and SWH This includes operating, maintenance and depreciation costs of ORV system, SMV system and SWH.

Then, the expansion optimization method of the LNG vaporization system of the present invention determines whether the operating costs of the ORV system, SMV system and SWH for each year of the year-by-year time zone for the case of the ORV system and SMV system to vaporize LNG is stored (S90). ). Here, the case of the ratio of ORV system and SMV system to vaporize LNG is selected by decreasing the ratio of ORV system by 10% from 100% to 0% and increasing the ratio of SMV system by 10% from 0% to 100%. .

As a result of the determination in step S90, if the operating costs of the ORV system, SMV system, and SWH for each year of the ORV system and SMV system to vaporize LNG were not stored, the optimization method for expanding the LNG vaporization system of the present invention. Return to the step S60, and if the operating costs of the ORV system, SMV system and SWH for each year of the ORV system and SMV system to vaporize LNG is stored, select the case of the minimum operating cost among the stored operating costs (S100).

Further, the expansion optimization method of the LNG vaporization system of the present invention is to expand the ORV system or to expand the SMV system to fit the case of the minimum operating costs selected in step S100 in the current gasification system status of the natural gas production base of step S10. (S110).

1 is a flow chart illustrating a method for optimizing the expansion of the LAN vaporization system according to an embodiment of the present invention.

Claims (9)

Inputting the total natural gas production amount to be produced in the next year at the natural gas production base to which the LNG vaporization system is to be expanded; Inputting a delivery pattern of natural gas for each year of the past year of the natural gas production base; Calculating the amount of natural gas output per year of the following year of the natural gas production base; Inputting seawater temperature for each year of the past year of the natural gas production base; Calculating an efficiency of an annual time zone ORV system of the natural gas production base according to the seawater temperature of the natural gas production base in the past year; Calculating the NG production capacity of the natural gas production base at each time zone; Setting and inputting a case for a ratio of the ORV system and the SMV system to vaporize LNG; Calculating the required radix of the ORV system, the SMV system, and the SWH by the set time of the next year according to the set case according to the amount of natural gas discharged by the annual time zone of the following year; Inputting operating costs of the ORV system, the SMV system, and the SWH; Calculating and storing operating costs of the ORV system, the SMV system, and the SWH according to the following yearly time zones; Calculating operating costs of the ORV system, the SMV system, and the SWH for each case of the ORV system and the SMV system according to the following yearly time zone; And selecting a case of a minimum operating cost among the stored operating costs of the ORV system, the SMV system, and the SWH according to the stored yearly time zone of the following year. The method according to claim 1, The outgoing pattern of natural gas by time zone of the past year of the natural gas production base, The method of optimizing the expansion of the LAN gas evaporation system, characterized in that the natural gas output by the year of the past year of the natural gas production base divided by the total amount of the previous year of the natural gas production base. The method according to claim 1, The amount of natural gas discharged per year of the following year of the natural gas production base, The expansion optimization method of the LAN gas evaporation system, characterized in that to calculate by multiplying the total natural gas production to be produced in the next year and the emission pattern of the natural gas for each time zone in the past year. The method according to claim 1, The annual production time of the natural gas production base NG, Efficiency optimization of the ORV system for each time zone according to the sea water temperature × evaporation capacity of the ORV system + vaporization capacity of the SMV system for each time zone + capacity of SWH for each time zone annually optimization method of expansion. The method according to claim 1, The case for the ratio of the ORV system and the SMV system to vaporize the LNG, And reducing the ratio of the ORV system by 10% from 100% to 0% and increasing the ratio of the SMV system by 10% from 0% to 100%. The method according to claim 1, Operating costs of the ORV system, the SMV system, and the SWH for each year time zone, It is characterized in that the required period of the ORV system by the annual time zone × operating cost of the ORV system + the required period of the SMV system by the yearly time zone × operating cost of the SMV system + required period of the SWH × operating cost of the SMV system Expansion Optimization Method of LGN Vaporization System. The method according to claim 1, The operating cost of the ORV system, the SMV system and the SWH, The expansion optimization method of the LAN vaporization system, characterized in that it comprises the operating cost, maintenance cost and depreciation cost of the ORV system, the SMV system and the SWH. The method according to claim 1, Inputting a current state of the current vaporization system of the natural gas production base; And further expanding the ORV system or expanding the SMV system so as to fit the case of the minimum operation cost selected from the current gasification system status of the natural gas production base. . The method according to claim 8, The current state of the gasification system of the natural gas production base, Head of the ORV system currently installed in the natural gas production base; The nose of the SMV system currently installed in the natural gas production base; A nose of the SWH currently installed in the natural gas production base; Vaporization capacity of the ORV system currently installed at the natural gas production base; A vaporization capacity of the SMV system currently installed at the natural gas production base; Expansion optimization method of the LAN gasification system comprising the capacity of the SWH currently installed in the natural gas production base.

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