KR20200101063A - Refrigerant Charging System And Method For Reliquefaction Cycle - Google Patents

Abstract

Disclosed are a system and a method for filling a reliquefaction cycle refrigerant. The system for filling a liquefaction cycle refrigerant of the present invention includes: a mixed refrigerant circulating part provided on a ship and allowing a mixed refrigerant for reliquefying boil off gas to be circulated; a refrigerant filling tank provided on a front end of the mixed refrigerant circulating part and supplying the mixed refrigerant required in the mixed refrigerant circulating part; and a mixed refrigerant control part measuring a composition of the mixed refrigerant in the refrigerant filling tank in real time and controlling the mixed refrigerant to supply the same to the mixed refrigerant circulating part by mixing the same in advance in the refrigerant filling tank with the composition of the mixed refrigerant required in the mixed refrigerant circulating part. Therefore, the system for filling a reliquefaction cycle refrigerant can effectively reliquefy the BOG.

Description

Refrigerant Charging System And Method For Reliquefaction Cycle

The present invention relates to a re-liquefaction cycle refrigerant filling system and method, and more particularly, to re-liquefy natural gas by circulating a mixed refrigerant in a mixed refrigerant circulation unit, and providing a refrigerant filling tank at the front end of the mixed refrigerant circulation unit, and The composition of the mixed refrigerant is measured in real time in the filling tank, and the measured value is compared with the designed mixed refrigerant composition, and the mixed refrigerant is mixed in advance in the refrigerant filling tank and supplied to the mixed refrigerant circulation unit with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit. It relates to a reliquefaction cycle refrigerant filling system and method.

Natural gas, which is mainly composed of methane, is attracting attention as an eco-friendly fuel because there is little emission of environmental pollutants during combustion. Liquefied Natural Gas (LNG) is obtained by liquefying natural gas by cooling it to about -163°C under normal pressure. Since its volume is reduced to about 1/600 compared to when it is in a gaseous state, it is suitable for long-distance transportation through sea. Very suitable. Therefore, natural gas is mainly stored and transported in a liquefied natural gas state that is easy to store and transport.

Since the liquefaction point of natural gas is a cryogenic temperature of about -163°C at normal pressure, the LNG storage tank is generally insulated to keep the LNG in a liquid state. However, although the LNG storage tank is insulated, there is a limit to blocking external heat, and since the external heat is continuously transferred to the LNG storage tank, LNG is continuously natural in the LNG storage tank during the LNG transportation process. It is vaporized to generate boil-off gas (BOG).

If boil-off gas is continuously generated in the LNG storage tank, it is a factor that increases the internal pressure of the LNG storage tank. If the internal pressure of the storage tank exceeds the set safety pressure, it may cause an emergency such as rupture of the tank. Therefore, the boil-off gas must be discharged to the outside of the storage tank using a safety valve. However, since boil-off gas is a kind of LNG loss, it is an important problem in transport efficiency and fuel efficiency of LNG, and thus various methods for treating boil-off gas generated in a storage tank are used.

In recent years, a method of using boil-off gas by a fuel consumer such as an engine of a ship, a method of re-liquefying the boil-off gas and recovering it to a storage tank, or a method of using these two methods in combination have been developed and applied.

In the case of applying the reliquefaction cycle to reliquefy the boil-off gas on the ship, a representative liquefaction method is a process using the SMR cycle and the C3MR cycle. The C3MR cycle (Propane-precooled Mixed Refrigerant Cycle) is a process in which natural gas is cooled using a single propane refrigerant, and then liquefied and supercooled using a mixed refrigerant, and the SMR cycle (Single Mixed Refrigerant Cycle) consists of a plurality of components. This is a process of liquefying natural gas using the mixed refrigerant.

Both the SMR cycle and the C3MR cycle include a process using a mixed refrigerant. In a cycle using such a mixed refrigerant, when the composition ratio of the mixed refrigerant changes due to leakage of the refrigerant while the liquefaction process proceeds, the liquefaction efficiency is degraded. Therefore, it is necessary to supplement the insufficient refrigerant components to maintain the mixed refrigerant composition ratio.

To this end, it is difficult and time consuming to fill the insufficient refrigerant while continuously measuring the composition ratio of the mixed refrigerant, and there is a problem that the reliquefaction cycle is difficult to operate normally until the composition ratio of the mixed refrigerant is recovered, and the reliquefaction efficiency is low. .

The present invention is to solve this problem, and propose a system capable of maintaining the reliquefaction efficiency of the reliquefaction cycle by rapidly replenishing the mixed refrigerant in the reliquefaction cycle.

According to an aspect of the present invention for solving the above problem, a mixed refrigerant circulation unit provided on a ship and circulating a mixed refrigerant for reliquefying the boil-off gas;

A refrigerant filling tank provided at a front end of the mixed refrigerant circulating unit and supplying the mixed refrigerant required for the mixed refrigerant circulating unit;

Mixing in which the composition of the mixed refrigerant is measured in real time in the refrigerant filling tank, and the mixed refrigerant is mixed in advance in the refrigerant filling tank with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit and supplied to the mixed refrigerant circulation unit. Refrigerant control unit; There is provided a reliquefaction cycle refrigerant filling system comprising a.

Preferably, the system comprises: a cargo tank provided on the ship and storing LNG; A hydrocarbon storage tank provided on the ship and storing hydrocarbons (CnHn) including methane and ethane; And a nitrogen generator provided on the ship to generate nitrogen and supply it to the ship. In addition, the mixed refrigerant may be a gas in which BOG (boil off gas) generated in the cargo tank, nitrogen, and hydrocarbons are mixed.

Preferably, the system includes: a first valve provided downstream of the hydrocarbon storage tank and controlling the flow rate of the hydrocarbon supplied to the refrigerant filling tank; And

A second valve provided downstream of the nitrogen generator to control a flow rate of the nitrogen supplied to the refrigerant filling tank; It may further include.

Preferably, the mixed refrigerant control unit includes a gas chromatography unit for measuring the composition of the mixed refrigerant in the refrigerant filling tank; A pressure transmitter for measuring the pressure of the refrigerant filling tank; And an automatic control unit receiving the measured values from the gas chromatography unit and the pressure transmitter and adjusting the flow rates of the first and second valves. It may further include.

Preferably, the system comprises: a compressor for receiving and compressing BOG from the cargo tank; A third valve provided between the compressor and the refrigerant filling tank; And a fourth valve provided between the cargo tank and the refrigerant filling tank. It may further include.

Preferably, in the automatic control unit, when the pressure of the cargo tank is higher than the pressure of the refrigerant filling tank, the fourth valve is opened to supply the BOG from the cargo tank to the refrigerant filling tank, and the pressure of the refrigerant filling tank is When the pressure of the cargo tank is higher than the pressure of the cargo tank, the third valve may be opened to control the BOG compressed through the compressor to be supplied to the refrigerant filling tank.

Preferably, the mixed refrigerant circulation unit comprises: a refrigerant compressor for compressing the mixed refrigerant; A cooler receiving and cooling the mixed refrigerant compressed from the refrigerant compressor; And a heat exchanger for reliquefying the boil-off gas by exchanging the mixed refrigerant cooled by the cooler with the boil-off gas. Including, the mixed refrigerant from the refrigerant filling tank may be supplied to the front end of the refrigerant compressor.

Preferably, in the system, when an abnormality occurs in reliquefaction performance due to maintenance of the mixed refrigerant circulation unit or a composition change of the mixed refrigerant circulating the mixed refrigerant circulation unit, the mixed refrigerant of the mixed refrigerant circulation unit is onboard a gas combustion unit (GCU). ) Alternatively, the mixed refrigerant may be sent to the cargo tank and removed, and the mixed refrigerant may be mixed in advance in the refrigerant filling tank with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit prior to the driving of the mixed refrigerant circulation unit and supplied to the mixed refrigerant circulation unit. .

According to another aspect of the present invention, a mixed refrigerant circulation unit is provided on the ship to reliquefy the boil-off gas generated in the cargo tank by cooling heat of the mixed refrigerant,

A refrigerant filling tank is provided in front of the mixed refrigerant circulation unit, and the composition of the mixed refrigerant is measured in real time in the refrigerant filling tank, and the composition of the mixed refrigerant required for the mixed refrigerant circulation unit is mixed in advance in the refrigerant filling tank. A reliquefaction cycle refrigerant filling method is provided, characterized in that the refrigerant is mixed to supply the mixed refrigerant required for the mixed refrigerant circulation unit.

Preferably, in the reliquefaction cycle refrigerant filling method, when the pressure of the cargo tank is higher than the pressure of the refrigerant filling tank, BOG is supplied from the cargo tank to the refrigerant filling tank in free flow, and the pressure of the refrigerant filling tank is the When the pressure of the cargo tank is higher than the pressure of the cargo tank, the BOG generated from the cargo tank can be compressed and supplied to the refrigerant filling tank.

Through the reliquefaction cycle refrigerant filling system and method of the present invention, the total amount of the mixed refrigerant is removed for maintenance of the mixed refrigerant cycle, or when the reliquefaction performance is abnormal due to a change in the composition of the mixed refrigerant due to refrigerant leakage, etc. In the case of removing the mixed refrigerant, the mixed refrigerant required for driving the mixed refrigerant cycle is required to quickly drive the mixed refrigerant cycle by mixing the mixed refrigerant in the refrigerant filling tank in advance with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit and supplying it to the mixed refrigerant circulation unit. Can be filled.

In this way, while measuring the composition of the mixed refrigerant in the refrigerant filling tank in real time, the mixed refrigerant required for the mixed refrigerant cycle can be prepared in advance and immediately supplied to the mixed refrigerant circulation unit, so that the reliquefaction cycle can be driven quickly, and the designed mixed refrigerant Since the composition of can be stably maintained, the reliquefaction performance can be prevented from deteriorating, and BOG can be effectively reliquefied.

1 is a diagram schematically showing a reliquefaction cycle refrigerant filling system according to an embodiment of the present invention.

In order to fully understand the operational advantages of the present invention and the object achieved by the implementation of 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 configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, in adding reference numerals to elements of each drawing, it should be noted that only the same elements are marked with the same numerals as possible, even if they are indicated on different drawings.

1 schematically shows a reliquefaction cycle refrigerant filling system according to an embodiment of the present invention. Hereinafter, a reliquefaction cycle refrigerant filling system according to an embodiment of the present invention will be described with reference to FIG. 1.

In an embodiment of the present invention described later, the ship may be any type of ship in which an engine capable of using liquefied gas as a fuel for a propulsion engine or a power generation engine is installed or using liquefied gas as a fuel. Representatively, ships with self-propelled capabilities such as LNG carriers, liquid hydrogen carriers, and LNG regasification vessels, as well as LNG Floating Production Storage Offloading (FPSO), and LNG Floating Storage Regasification Unit (FSRU). It may also include offshore structures that are not capable but are floating on the sea. However, in the following embodiments, a liquefied gas carrier or a liquid hydrogen carrier will be described as an example.

In addition, this embodiment can be transported by liquefying the gas at a low temperature, and can be applied to a re-liquefaction cycle of all types of liquefied gas in which boil-off gas is generated in a stored state. These liquefied gases are, for example, liquefied petrochemicals such as LNG (Liquefied Natural Gas), LEG (Liquefied Ethane Gas), LPG (Liquefied Petroleum Gas), Liquefied Ethylene Gas, and Liquefied Propylene Gas. It can be gas. However, in the embodiments to be described later, a representative liquefied gas, LNG, is applied as an example.

As shown in FIG. 1, the reliquefaction cycle refrigerant filling system according to an embodiment of the present invention includes a cargo tank T provided on a ship and storing LNG, and a mixture for reliquefaction of boil-off gas provided on the ship. It includes a mixed refrigerant circulation unit 100 through which the refrigerant is circulated. A compressor 600 for receiving and compressing BOG from the cargo tank is provided downstream of the cargo tank.

In this embodiment, a refrigerant filling tank 200 for supplying the mixed refrigerant required for the mixed refrigerant circulation unit is provided at the front end of the mixed refrigerant circulation unit, and a mixed refrigerant control unit 300 is provided to prevent the mixed refrigerant mixed in the refrigerant charging tank. The composition is measured in real time and compared with the designed mixed refrigerant composition, and adjusted to be supplied to the mixed refrigerant circulation unit by mixing the mixed refrigerant in advance in the refrigerant filling tank according to the composition of the mixed refrigerant required for the mixed refrigerant circulation unit.

And the hydrocarbon storage tank 400 for storing the hydrocarbon (CnHn) including methane, ethane, and in this embodiment, the nitrogen generator for supplying on board to generate nitrogen (N ₂ generator, 500) is provided in the vessel.

The mixed refrigerant that circulates through the reliquefaction cycle and supplies cold heat for reliquefaction of the boil-off gas may be a mixture of BOG (boil off gas), nitrogen, and hydrocarbon (CnHn) generated in a cargo tank. In particular, BOG generated in the cargo tank is made of almost pure methane (CH ₄ ), so the mixed refrigerant in the reliquefaction cycle is nitrogen (N) generated in the nitrogen generator, CH ₄ generated in the cargo tank, and supplied from the hydrocarbon storage tank. It contains C ₂ H6 ~ C ₅ H ₁₀ as the main component.

The mixed refrigerant control unit 300 includes a gas chromatography unit 310 that measures a composition of a mixed refrigerant in a refrigerant filling tank in real time, a pressure transmitter 320 that measures a pressure in the refrigerant filling tank, a gas chromatography unit, and It is configured to include an automatic control unit 330 that receives the measured value from the pressure transmitter and adjusts the flow rate of each component supplied to the refrigerant filling tank.

In order to control the supply amount of each component constituting the mixed refrigerant, a first valve V1 is provided downstream of the hydrocarbon storage tank 400 to adjust the flow rate of the hydrocarbon supplied to the refrigerant filling tank, and the nitrogen generator 500 A second valve V2 is provided downstream to control the flow rate of nitrogen supplied to the refrigerant filling tank.

The mixed refrigerant control unit compares the real-time measurement value of the mixed refrigerant measured from the gas chromatography unit and the pressure transmitter with the value designed for the composition of the mixed refrigerant in the reliquefaction cycle, and opens the first and second valves according to the signal of the automatic control unit. By controlling, the flow rate of hydrocarbon and nitrogen to be supplied to the refrigerant filling tank is controlled.

Meanwhile, in order to control the supply of BOG from the cargo tank to the refrigerant filling tank, a third valve V3 is provided between the compressor 600 and the refrigerant filling tank 200, and the cargo tank T and the refrigerant filling tank 200 Fourth valves V4 are provided between them, respectively. That is, the third valve is provided in the line supplied from the cargo tank to the refrigerant filling tank through the compressor, and the fourth valve is provided in the line where the BOG is supplied to the refrigerant filling tank directly from the cargo tank without passing through the compressor.

In the automatic control unit 330, when the pressure of the cargo tank is higher than the pressure of the refrigerant filling tank, the fourth valve V4 is opened to supply BOG in a free flow from the cargo tank to the refrigerant filling tank, and the pressure of the refrigerant filling tank is When it is higher than the pressure of the tank, the third valve V3 is opened to control the BOG compressed through the compressor to be supplied to the refrigerant filling tank. Thus, free flow BOG and compressed BOG can be selectively supplied to the refrigerant filling tank by comparing the pressure of the refrigerant filling tank with the pressure of the cargo tank. A control unit (not shown) for controlling opening/closing of the third and fourth valves by comparing the pressure of the cargo tank by receiving the pressure value of the refrigerant filling tank from the pressure transmitter and the automatic control unit may be additionally provided.

Meanwhile, the mixed refrigerant circulation unit 100 includes a refrigerant compressor 110 that compresses the mixed refrigerant, a cooler 120 that receives and cools the mixed refrigerant compressed from the refrigerant compressor, and the mixed refrigerant cooled from the cooler is a boil-off gas. It includes a heat exchanger 130 for re-liquefying the boil-off gas by heat exchange with. The mixed refrigerant circulation unit may be any reliquefaction cycle using a mixed refrigerant, including an SMR cycle and a C3MR cycle.

The mixed refrigerant is supplied from the refrigerant filling tank to the front end of the refrigerant compressor, and a valve VR for controlling the supply of the mixed refrigerant is provided in a line connecting the refrigerant filling tank and the mixed refrigerant circulation unit.

In the system of this embodiment, when it is necessary to remove the mixed refrigerant from the mixed refrigerant circulation unit for maintenance of the mixed refrigerant circulation unit, or when an abnormality in the reliquefaction performance occurs due to a composition change of the mixed refrigerant circulating the mixed refrigerant circulation unit due to refrigerant leakage or the like, The entire amount of mixed refrigerant in the mixed refrigerant circulation section can be removed by sending it to the onboard gas combustion unit (GCU) or cargo tank. Thereafter, prior to driving the mixed refrigerant circulation unit, the mixed refrigerant may be mixed in advance in the refrigerant filling tank with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit, and then quickly supplied to the mixed refrigerant circulation unit.

As described above, by applying the system of this embodiment, when the composition of the mixed refrigerant is measured in real time while the composition ratio of the mixed refrigerant is changed due to refrigerant leakage or the like, refrigerant filling is required or the mixed refrigerant is removed for maintenance, in the mixed refrigerant circulation unit. The total amount of mixed refrigerant is removed, and the mixed refrigerant is prepared in the refrigerant filling tank in advance and can be quickly supplied to the mixed refrigerant circulation unit, so that the reliquefaction cycle can be restored quickly.

Through this embodiment, since the composition of the designed mixed refrigerant can be stably maintained, the reliquefaction performance can be prevented from deteriorating, and the BOG can be effectively reliquefied.

It is obvious to those of ordinary skill in the art that the present invention is not limited to the above embodiments, and can be implemented with various modifications or variations within the scope of the technical gist of the present invention. I did it.

T: cargo tank
100: mixed refrigerant circulation unit
110: refrigerant compressor
120: cooler
130: heat exchanger
200: refrigerant filling tank
300: mixed refrigerant control unit
310: gas chromatography unit
320: pressure transmitter
330: automatic control unit
400: hydrocarbon storage tank
500: nitrogen generator
600: compressor
V1: first valve
V2: second valve
V3: 3rd valve
V4: fourth valve

Claims (10)

A mixed refrigerant circulation unit provided on the ship and circulating a mixed refrigerant for reliquefying the boil-off gas;
A refrigerant filling tank provided at a front end of the mixed refrigerant circulating unit and supplying the mixed refrigerant required for the mixed refrigerant circulating unit; And
While measuring the composition of the mixed refrigerant in the refrigerant filling tank in real time, adjusting the mixed refrigerant to be supplied to the mixed refrigerant circulation unit by mixing the mixed refrigerant in advance in the refrigerant filling tank with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit. Mixed refrigerant control unit; Reliquefaction cycle refrigerant filling system comprising a. The method of claim 1,
A cargo tank provided on the ship and storing LNG;
A hydrocarbon storage tank provided on the ship and storing hydrocarbons (CnHn) including methane and ethane; And
A nitrogen generator provided on the ship to generate nitrogen and supply it to the ship; Including more,
The mixed refrigerant is a reliquefaction cycle refrigerant filling system, characterized in that the mixed refrigerant is a mixture of BOG (boil off gas), nitrogen, and hydrocarbon generated in the cargo tank. The method of claim 2,
A first valve provided downstream of the hydrocarbon storage tank to control a flow rate of the hydrocarbon supplied to the refrigerant filling tank; And
A second valve provided downstream of the nitrogen generator to control a flow rate of the nitrogen supplied to the refrigerant filling tank; Reliquefaction cycle refrigerant filling system further comprising a. The method of claim 3, wherein the mixed refrigerant control unit
A gas chromatography unit measuring the composition of the mixed refrigerant in the refrigerant filling tank;
A pressure transmitter for measuring the pressure of the refrigerant filling tank; And
An automatic control unit receiving the measured value from the gas chromatography unit and the pressure transmitter and adjusting flow rates of the first and second valves; Reliquefaction cycle refrigerant filling system comprising a. The method of claim 4,
A compressor that receives and compresses BOG from the cargo tank;
A third valve provided between the compressor and the refrigerant filling tank; And
A fourth valve provided between the cargo tank and the refrigerant filling tank; Reliquefaction cycle refrigerant filling system further comprising a. The method of claim 5,
In the automatic control unit, when the pressure of the cargo tank is higher than the pressure of the refrigerant filling tank, the fourth valve is opened to supply BOG from the cargo tank to the refrigerant filling tank, and the pressure of the refrigerant filling tank is When the pressure is higher than the pressure, the third valve is opened to control the BOG compressed through the compressor to be supplied to the refrigerant filling tank. The method of claim 1, wherein the mixed refrigerant circulation unit
A refrigerant compressor compressing the mixed refrigerant;
A cooler receiving and cooling the mixed refrigerant compressed from the refrigerant compressor; And
A heat exchanger for reliquefying the boil-off gas by exchanging the mixed refrigerant cooled by the cooler with the boil-off gas; Including,
The reliquefaction cycle refrigerant filling system, characterized in that the mixed refrigerant is supplied from the refrigerant filling tank to a front end of the refrigerant compressor. The method of claim 7,
When an abnormality occurs in reliquefaction performance due to maintenance of the mixed refrigerant circulation unit or a composition change of the mixed refrigerant circulating the mixed refrigerant circulation unit, the mixed refrigerant of the mixed refrigerant circulation unit is transferred to a gas combustion unit (GCU) or the cargo tank on board. Send and remove,
A reliquefaction cycle refrigerant filling system, characterized in that prior to driving of the mixed refrigerant circulation unit, the mixed refrigerant is mixed in advance in the refrigerant filling tank with the composition of the mixed refrigerant required for the mixed refrigerant circulation unit and supplied to the mixed refrigerant circulation unit. A mixed refrigerant circulation part is provided on the ship to re-liquefy the evaporated gas generated from the cargo tank with the cooling heat of the mixed refrigerant.
A refrigerant filling tank is provided at a front end of the mixed refrigerant circulation unit, and the composition of the mixed refrigerant in the refrigerant filling tank is measured in real time, and the composition of the mixed refrigerant required for the mixed refrigerant circulating unit is determined in advance in the refrigerant filling tank. A reliquefaction cycle refrigerant filling method, characterized in that the mixed refrigerant is mixed to supply the mixed refrigerant required for the mixed refrigerant circulation unit. The method of claim 9,
When the pressure of the cargo tank is higher than the pressure of the refrigerant filling tank, BOG is supplied from the cargo tank to the refrigerant filling tank in free flow, and when the pressure of the refrigerant filling tank is higher than the pressure of the cargo tank, BOG generated from the cargo tank Is compressed and supplied to the refrigerant filling tank.

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