KR20160069824A - High Pressure Pump Pressurizing System and Method for LNG Regasification System - Google Patents

Abstract

The present invention relates to a system and a method for pressurizing using a high pressure pump for a liquefied natural gas (LNG) regasification system which simplify a structure for regasifying LNG or pressurizing the LNG to a pressure required by an LNG user in a marine structure for LNG management, satisfy a pressurizing condition, and reduce initial investment expenses and maintenance costs. According to the present invention, the system for pressurizing using a high pressure pump for an LNG regasification system comprises: a high pressure pump to pressurize LNG; a connection line to supply the LNG pressurized by the high pressure pump to an LNG user; an opening/closing valve disposed on the connection line on a discharge side of the high pressure pump; a back pressure forming means which is disposed on the connection line, and prevents overload of the high pressure pump; and a control panel to control operation of the high pressure pump, the opening/closing valve, and the back pressure forming means.

Description

TECHNICAL FIELD [0001] The present invention relates to a high pressure pump pressurizing system and method for an LNG regasification system,

The present invention relates to a system and method for pressurizing a high pressure pump of an LNG regasification system, and more particularly, to a system and method for pressurizing a high pressure pump of an LNG regasification system, To a system and method for high pressure pump pressurization of an LNG regasification system capable of reducing initial investment cost and maintenance cost.

In recent years, demand for clean natural gas (LNG), which is clean fuel and low in cost, is increasing rapidly. In particular, with the development of seabed mining technology, offshore plants producing and transporting natural gas buried in the seabed are in the spotlight. As a result, liquefied natural gas carrier (LNGC), liquefied natural gas - (LNG-FPSO) and LNG-Floating Storage and regasification unit (LNG-FSRU), LNG-Regasification Vessel , LNG-RV) (hereinafter referred to as "LNG-operated offshore structures").

Such LNG-operated offshore structures, especially LNG-operated offshore structures such as LNG-FSRU and LNG-RV, require re-gasification and pressurization to the pressure required by the customer.

FIG. 1 is a schematic view schematically showing a configuration for pressurizing liquefied natural gas.

As described above, the installation of the small high-pressure pump has a disadvantage that the initial investment cost, maintenance and repair costs are high, and system energy increases.

(Document 1) Korean Patent Registration No. 10-0779779 (November 20, 2007) (Document 2) Korean Patent Publication No. 10-2008-0013223 (Feb. 23, 2008)

Generally, as shown in FIG. 1, the high-pressure pump 100 is used to pressurize the LNG-FSRU or the LNG-RV liquefied natural gas to a pressure required by the regeneration and customer. The discharge valve 300 of the high-pressure pump 100 is a globe valve having a large size. However, it is difficult to adjust the flow rate and it is not easy to satisfy the back pressure required for the operation of the high-pressure pump 100. If the system pressure is not suitable for the back pressure of the high pressure pump 100, the pump operation is overloaded, resulting in malfunction of the device, burnout of the pump motor, and risk of fire due to sparking.

In order to prevent this, a small high-pressure pump 20 is additionally installed to raise the pressure of the system up to a pressure necessary for the operation of the high-pressure pump 100, and then start the operation. That is, the small-sized high-pressure pump 20 generates a back pressure required at the rear end of the high-pressure pump 100 and starts operation of the high-pressure pump 100 to prevent overload. Reference numeral 21 denotes a discharge valve of the small high-pressure pump 20.

The present invention for solving these problems is to provide a LNG-operating offshore structure which can simplify a construction for regenerating liquefied natural gas or pressurize it with a pressure required by a customer, and can reduce initial investment cost and maintenance cost, To provide a high pressure pump pressurization system and method for a regasification system.

According to an aspect of the present invention, there is provided a high pressure pump for pressurizing liquefied natural gas; A connection line for supplying the pressurized liquefied natural gas from the high-pressure pump to a customer; An on-off valve provided on a discharge side connection line of the high-pressure pump; A back pressure forming means provided in the connection line for preventing an overload of the high pressure pump; And a control panel for controlling operations of the high-pressure pump, the on-off valve, and the back pressure forming means.

In one aspect, the back pressure forming means includes a bypass line bypassing the on-off valve and connected to the connection line; At least one control valve provided on the bypass line; And a shutdown valve provided at a rear end of the control valve and before the point at which the bypass line is connected to the connection line.

In one aspect, the control panel opens the shutdown valve and the control valve when the high-pressure pump is started, closes the control valve and the shutdown valve when the discharge-side pressure of the high-pressure pump reaches the operating pressure, And at the same time, the open / close valve is controlled to open.

In one aspect, the control panel is configured to open the shutdown valve at the start of operation of the high-pressure pump, adjust the flow rate to the control valve, and notify whether the discharge-side pressure of the high-pressure pump reaches the operating pressure .

According to another aspect of the present invention, there is provided a method for controlling a liquefied natural gas, comprising: a pressurizing step for pressurizing liquefied natural gas introduced through a high-pressure pump; An initial pressurized LNG bypass step of guiding the liquefied natural gas to be pressurized and discharged to bypass the on-off valve of the high-pressure pump; A determination step of determining whether a discharge side pressure of the high pressure pump reaches an operation pressure of the high pressure pump; And a normal operating step of closing the bypass path and opening the on-off valve of the high-pressure pump when it is determined that the operating pressure has been reached in the determining step, a high-pressure pump pressurization method of the LNG regeneration system / RTI >

According to still another aspect of the present invention, there is provided a method for producing a liquefied natural gas, comprising: a pressurizing step for pressurizing liquefied natural gas introduced through a high-pressure pump; An initial pressurized LNG bypass step of guiding the liquefied natural gas to be pressurized and discharged to bypass the on-off valve of the high-pressure pump; A determination step of determining whether a discharge side pressure of the high pressure pump reaches an operation pressure of the high pressure pump; And a high-pressure pump pressurization system of an LNG regeneration system that closes the path of the bypass step and notifies whether the discharge-side pressure of the high-pressure pump reaches the operating pressure when it is determined that the operating pressure has been reached in the determining step Method is provided.

In another aspect of the present invention, it is preferable to maintain the LNG bypass step when it is determined that the operating pressure has not been reached in the determining step.

As described above, according to the present invention, it is possible to simplify the construction for regenerating LNG in an offshore structure for LNG operation or pressurize it to a pressure required by a customer, while satisfying pressurization conditions and reducing initial investment cost and maintenance cost A high pressure pump pressurization system and method of an LNG regasification system are provided.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a configuration for pressing an LNG according to the prior art.
FIG. 2 is a schematic view showing a high-pressure pump pressurizing system of the LNG regeneration system according to the present invention, and FIG.
3 is a flow chart showing a method for pressurizing a high-pressure pump of an LNG regeneration system according to the present invention.

The high pressure pump pressurization system and method of the LNG regasification system according to the present invention as described below can be applied not only to the LNG carrier but also to any plant, ship or offshore structure that needs to vaporize or pressurize the cargo of the liquid cargo .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted for the sake of clarity and conciseness.

The high pressure pump pressurization system and method of the LNG regasification system according to the present invention can simplify the construction for pressurizing liquefied natural gas in an offshore structure that operates liquefied natural gas while satisfying pressurization conditions, In order to reduce the cost of the system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A high pressure pump pressurizing system and method of an LNG regeneration system according to a preferred embodiment of the present invention will now be described with reference to the accompanying drawings.

First, a high-pressure pump pressurizing system of the LNG regeneration system according to the present invention will be described with reference to FIG. The high pressure pump pressurizing system of the LNG regeneration system according to the present invention comprises a high pressure pump 100 for pressurizing the incoming liquefied natural gas, as shown in FIG. 2; A connection line 200 for supplying liquefied natural gas pressurized by the high-pressure pump 100 to a high-pressure vaporizer C or a customer; An on-off valve (300) provided on a discharge side connection line (200) of the high-pressure pump (100); A back pressure forming means provided on the connection line (200) for forming a back pressure to prevent an overload of the high pressure pump (100); And a control panel 400 for controlling operations of the high-pressure pump 100, the on-off valve 300, and the back pressure forming means.

The high-pressure pump 100 is preferably operated at an operating pressure of 100 bar or more.

Since the connection line 200 is preferably made of a material capable of withstanding high pressure, a conventional one can be employed, and thus a detailed description thereof will be omitted. The open / close valve 300 may be, for example, a globe valve or any other type capable of performing opening and closing operations, and may be a manual valve or an automatic opening / closing valve controlled by the control panel .

Subsequently, the back pressure forming means includes a bypass line 510 connected to the connection line 200 by bypassing the on-off valve 300, and one or more control valves (not shown) provided on the bypass line 510 And a shutdown valve 530 disposed at a rear end of the control valve 520 and before the point where the bypass line 510 is connected to the connection line 200. The control valve 520 is provided to regulate the degree of opening and closing to regulate the flow rate, and the shutdown valve 530 can be fully opened and closed to supplement the control valve 520 which can not completely shut off the flow rate And may be installed at a position at a rear end of the control valve 520 and at a position where the bypass line 510 becomes one flow with the connection line 200. [

The control panel 400 opens the shutdown valve 530 included in the bypass line 510 and controls the opening and closing degree of the control valve 520 to control the flow rate of the high pressure pump 100, The control valve 520 and the shutdown valve 530 are closed and the open / close valve 300 is opened after the pressure on the discharge side of the shutoff valve 100 is pressurized to the operating pressure. When stopping the bypass flow, it is preferable that the control valve 520 and the shutdown valve 530 are closed simultaneously or the control valve 520 is closed first, and then the shutdown valve 530 is closed. Here, when the open / close valve 300 is manually configured, the control panel 400 notifies a signal indicating that the discharge side pressure of the booster pump has reached the operation pressure by an audible and / or visual signal, An operator manually opens the on-off valve 300 through the control panel 400 or manually.

The control panel 400 may be configured in a central control panel of a central control room of an offshore structure having a pressurized system.

As described above, the high-pressure pump pressurizing system of the LNG regeneration system of the present invention includes the bypass line 510 installed at the discharge side of the high-pressure pump 100, and the bypass line 510 is easily controlled, The valve 520 and the shutdown valve 530 capable of fully closing the path are provided so that the discharge side pressure of the high pressure pump 100 is pressurized to the operation pressure without additionally installing an expensive small high pressure pump, 100 is opened and the high-pressure pump 100 is operated normally.

That is, since the pipe connected to the discharge side of the high-pressure pump 100 is generally large in size, it is difficult to adjust the back pressure and accordingly the size of the valve is too large to control. However, according to the present invention, It is possible to easily pressurize the discharge side pressure of the high-pressure pump 100 by providing the bypass line 510 which can be constituted by a relatively small-sized pipe, and it is possible to employ a valve of a small size, . Further, the bypass line 510 may be configured instead of the small high-pressure pump to reduce installation cost, maintenance / repair cost, and energy consumption.

Next, the high-pressure pump pressurizing method of the LNG regeneration system will be described with reference to FIG. The method for pressurizing the high pressure pump of the LNG regeneration system according to the present invention includes a pressurization step (S100) for pressurizing the liquefied natural gas flowing through the high pressure pump (100) as shown in FIG. An initial pressurized LNG bypass step (S200) for guiding the liquefied natural gas to be pressurized and discharged to bypass the open / close valve (300) of the pressurization pump (100); A determination step (S300) of determining whether the discharge side pressure of the high pressure pump (100) has reached an operation pressure of the high pressure pump (100); And a normal operation step (S200) of closing the path of the bypass step (S200) and opening the on-off valve (300) of the high-pressure pump (100) when it is determined that the operating pressure is reached in the determining step (S300) S400).

If it is determined in step S300 that the operating pressure has not been reached, the LNG bypass step S200 is maintained.

In the normal operation step S400, the opening / closing valve 300 may be opened manually or automatically. In this case, when the high pressure pump 100 is started, the shutdown valve 530 is opened, It is possible to adjust the opening degree of the control valve 520 according to the required flow rate and notify whether or not the discharge side pressure of the high pressure pump 100 reaches the operating pressure.

The high pressure pump pressurization system and method of the LNG regasification system according to the present invention can be applied not only to the LNG carrier but also to any plant, ship or offshore structure that needs to vaporize or pressurize the cargo of the liquid cargo.

As described above, the high pressure pump pressurizing system and method of the LNG regeneration system according to the present invention can satisfy the pressurization conditions while simplifying the construction for pressurizing the liquefied natural gas in an offshore structure using liquefied natural gas, There is an advantage to reduce initial investment and maintenance costs.

As described above, the high pressure pump pressurizing system and method of the LNG regeneration system according to the present invention has been described with reference to the drawings. However, the present invention is not limited to the embodiments and drawings described above, It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention.

20: Small high pressure pump S100: Pressurization step
21: Discharge valve of small high-pressure pump S200: Initial pressurized LNG bypass step
100: High-pressure pump S300: Operation pressure judgment step
200: connection line S400: normal operation phase
300: opening / closing valve
400: control panel
510: Bypass line
520: Control valve
530: Shutdown valve

Claims (7)

A high pressure pump for pressurizing liquefied natural gas;
A connection line for supplying the pressurized liquefied natural gas from the high-pressure pump to a customer;
An on-off valve provided on a discharge side connection line of the high-pressure pump;
A back pressure forming means provided in the connection line for preventing an overload of the high pressure pump; And
And a control panel for controlling the operation of said high-pressure pump, said on-off valve and said back-pressure forming means. The method according to claim 1,
The back pressure forming means
A bypass line bypassing the on-off valve and connected to the connection line;
At least one control valve provided on the bypass line; And
And a shutdown valve provided at a rear end of the control valve and before the point where the bypass line is connected to the connection line. The method of claim 2,
The control panel
Closing valve and the control valve when the high-pressure pump is started, and closing the control valve and the shutdown valve when the discharge-side pressure of the high-pressure pump reaches the operating pressure, Pressure pump system of the LNG regasification system. The method of claim 2,
The control panel
Pressure pump system of an LNG regasification system configured to open the shutdown valve at the start-up of the high-pressure pump, adjust the flow rate to a control valve, and notify whether the discharge-side pressure of the high- . A pressurizing step of pressurizing the liquefied natural gas flowing through the high-pressure pump;
An initial pressurized LNG bypass step of guiding the liquefied natural gas to be pressurized and discharged to bypass the on-off valve of the high-pressure pump;
A determination step of determining whether a discharge side pressure of the high pressure pump reaches an operation pressure of the high pressure pump; And
And a normal operating step of closing the bypass path and opening the on-off valve of the high-pressure pump when it is determined that the operating pressure has been reached in the determining step. A pressurizing step of pressurizing the liquefied natural gas flowing through the high-pressure pump;
An initial pressurized LNG bypass step of guiding the liquefied natural gas to be pressurized and discharged to bypass the on-off valve of the high-pressure pump;
A determination step of determining whether a discharge side pressure of the high pressure pump reaches an operation pressure of the high pressure pump; And
The high pressure pump pressurization method of the LNG regeneration system for closing the path of the bypass step and notifying whether the discharge side pressure of the high pressure pump reaches the operating pressure when it is determined that the operating pressure has been reached in the determining step . The method according to claim 5 or 6,
And the LNG bypassing step is maintained when it is determined that the operating pressure has not been reached in the determining step.

Images