KR101903761B1 - Liquefied gas regasification system - Google Patents

Abstract

A liquefied gas regasification system is disclosed. A liquefied gas regeneration system according to an embodiment of the present invention includes a regeneration line for regenerating liquefied gas and supplying it to a customer, a first heat exchanger for successively heat-exchanging liquefied gas transferred along the regasification line, A first medium circulation line for circulating the first heat medium among the heat medium pressurized by the pressurizing pump to the suction drum via the first heat exchanger, a second medium circulation line for circulating the first heat medium through the first heat exchanger to the suction drum, A second medium circulation line for circulating the second heat medium among the heating medium pressurized by the pump to the suction drum via the second heat exchanger, a second medium circulation line provided at the front end of the first heat exchanger on the first medium circulation line, And a second heater provided at a front end of the second heat exchanger on the second medium circulation line for heat-exchanging the second heat medium with seawater to heat the first heat medium , The first heating medium is vaporized by the first heater and then re-liquefied and heat exchanged in the first heat exchanger, and the second heating medium is heated to the liquid state by the second heater and then heat-exchanged in the second heat exchanger have.

Description

[0001] LIQUEFIED GAS REGASIFICATION SYSTEM [0002]

The present invention relates to a liquefied gas regeneration system, and more particularly, to a liquefied gas regeneration system that vaporizes, processes, and supplies a liquefied gas to a customer.

In recent years, liquefied gas such as Liquefied Natural Gas (LNG), which is a clean energy source, has been widely used instead of gasoline or diesel as the interest in the environment such as emission of greenhouse gases and various air pollutants increases.

Liquefied natural gas is a colorless transparent cryogenic liquid that reduces the volume of natural gas taken from a gas field to an extremely low temperature of about -162 degrees Celsius and reduces its volume to 1/600. It is used to liquefy natural gas for easy storage and transportation, And is transported over a long distance from a production site to a destination such as a customer by a carrier or the like. The liquefied natural gas carrier is operated by sea to unload liquefied natural gas to the demand place on the land. Usually, the liquefied natural gas stored in the storage tank is unloaded to the land terminal as it is liquefied. And it is supplied to the demand places such as homes, industrial complexes and the like.

The land terminal equipped with such regeneration facilities can be economically advantageous when it is constructed in a natural gas market and where the demand is stable, but in the case of a demand where the demand for natural gas is limited in a seasonal, short- There is a problem that construction of a terminal is not economical due to high installation cost and management cost. In particular, there is a safety problem such as a casualty accident when the land terminal is broken due to natural disasters, and even if the liquefied natural gas transportation vessel transports liquefied natural gas to the demand point when the terminal of the land terminal breaks down, The transportation of natural gas using a conventional liquefied natural gas carrier has a limitation.

Recently, LNG RV (LNG Regasification Vessel) or LNG Regasification Vessel (LNG Regasification Vessel) or LNG Regasification Vessel (LNG Regasification Vessel), which is equipped with a re-gasification system in a liquefied natural gas carrier to supply natural gas directly to customers, And natural gas storage and regasification unit (FSRU) have been developed and operated.

Such a regasification system or regeneration facility is a method of vaporizing liquefied natural gas by exchanging cryogenic liquefied natural gas stored in a storage tank with a seawater or a heat transfer medium. , There is a problem that the durability of the regeneration facility is greatly lowered due to the corrosion of the equipment due to freezing of sea water or salt, and the reliability of liquefied natural gas regeneration performance is inferior because the temperature of seawater is not constant have. In addition, when the liquefied natural gas is vaporized by using the heat transfer medium, a separate heat source such as a boiler for heating the heat transfer medium is required, which is not environmentally friendly and is also inefficient in terms of energy consumption.

Therefore, it is required to research and develop liquefied natural gas such as liquefied natural gas effectively and efficiently to be recycled and sent to consumers.

Korean Patent Publication No. 10-2008-0085284 (published on September 24, 2008)

An embodiment of the present invention is to provide a liquefied gas regeneration system capable of improving regeneration efficiency and performance of liquefied gas.

An embodiment of the present invention seeks to provide a liquefied gas regeneration system that can improve the reliability of the liquefied gas regeneration process.

An embodiment of the present invention seeks to provide a liquefied gas regeneration system capable of stable liquefied gas regeneration process despite seawater temperature changes.

An embodiment of the present invention is to provide a liquefied gas regeneration system capable of effectively realizing regeneration of liquefied gas by utilizing low temperature seawater as a heat source.

An embodiment of the present invention is to provide a liquefied gas regeneration system capable of improving heat transfer efficiency and heat exchange efficiency between a liquefied gas and a heat medium.

The embodiment of the present invention is intended to provide a liquefied gas regeneration system capable of improving facility operation efficiency.

According to an aspect of the present invention, there is provided a method of regenerating a liquefied gas, comprising: a regeneration line regenerating liquefied gas to supply it to a customer, a first heat exchanger and a second heat exchanger sequentially heat- A first medium circulation line for circulating a first heat medium among the heating medium pressed by the pressure pump to the suction drum via the first heat exchanger, a second medium circulation line for circulating the first heat medium through the first heat exchanger to the suction drum, A second medium circulation line for circulating a second heat medium of the heating medium pressurized by the pump to the suction drum via the second heat exchanger, a second medium circulation line provided at a front end of the first heat exchanger on the first medium circulation line, A first heat exchanger provided on the upstream side of the second heat exchanger on the second medium circulation line to heat the second heat medium, And the second heat medium is re-liquefied and heat-exchanged in the first heat exchanger after being vaporized by the first heater, and the second heat medium is heat-exchanged by the second heater And is heat-exchanged in the second heat exchanger after being heated in a liquid state.

The heating medium may be provided as propane.

The pressurizing pump may pressurize the second heat medium entering the second heat exchanger to have a pressure of 6.54 barg or more.

Further comprising a pressure maintaining device for maintaining the pressure of the second heat medium entering the second heat exchanger at 6.54 barg or more, wherein the pressure maintaining device comprises a pressure sensor for sensing the pressure of the second heat medium entering the second heat exchanger, And a pressure regulating valve provided at a downstream end of the second heat exchanger on the second medium circulation line, wherein the pressure regulating valve can be operated based on pressure information of the second heat medium sensed by the pressure sensor .

Further comprising a vaporizing gas temperature regulating device for regulating the temperature of the vaporizing gas regenerated by the regeneration line, wherein the vaporizing gas temperature regulating device comprises a temperature sensor for detecting the temperature of the vaporizing gas and a temperature sensor for controlling the supply amount of the second heating medium And the temperature control valve can be controlled in operation based on temperature information of the vaporized gas sensed by the temperature sensor.

The flow control valve may further include temperature information of the first heat medium that is heat-exchanged through the first heat exchanger, internal pressure information of the suction drum, and temperature information of the first heat medium, And the temperature information of the heating medium supplied from the suction drum to the pressurizing pump.

And a seawater circulation line having a seawater pump for supplying and circulating seawater to the first heater and the second heater, respectively.

The seawater circulation line may be provided with a heater for auxiliary heating the seawater.

The heater may be provided with a first heater for heating seawater supplied to the second heater and a second heater for heating seawater supplied to the first heater.

The seawater circulation line includes a seawater intake valve for controlling the inflow of seawater, a seawater discharge valve for controlling the discharge of seawater, and a seawater discharge valve for returning the seawater having passed through the first heater or the second heater to the first heater And a recirculation valve provided in the recirculation line, wherein the seawater intake valve, the seawater discharge valve and the recirculation valve can be controlled in operation based on the temperature information of the seawater have.

The liquefied gas regeneration system according to the embodiment of the present invention has an effect of improving the regeneration efficiency and performance of the liquefied gas.

The liquefied gas regeneration system according to the embodiment of the present invention has the effect of improving the reliability of the liquefied gas regeneration process.

The liquefied gas regeneration system according to the embodiment of the present invention has an effect of effectively regenerating liquefied gas by utilizing low temperature seawater as a heat source.

The liquefied gas regeneration system according to the embodiment of the present invention has the effect of enabling stable liquefied gas regeneration process despite the change of the seawater temperature.

The liquefied gas regeneration system according to the embodiment of the present invention has an effect of improving the heat transfer efficiency and the heat exchange efficiency between the liquefied gas and the heat medium.

The liquefied gas regeneration system according to the embodiment of the present invention has an effect of improving facility operation efficiency.

1 is a conceptual diagram showing a liquefied gas regeneration system according to an embodiment of the present invention.
2 is a graph showing a temperature change of natural gas, a heating medium and seawater according to a pressure of a heating medium in a conventional second heat exchanger.
3 is a graph showing changes in temperature of natural gas, heat medium and seawater in the second heat exchanger according to the embodiment of the present invention.
4 is a conceptual diagram showing a liquefied gas regeneration system according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to fully convey the spirit of the present invention to a person having ordinary skill in the art to which the present invention belongs. The present invention is not limited to the embodiments shown herein but may be embodied in other forms. For the sake of clarity, the drawings are not drawn to scale, and the size of the elements may be slightly exaggerated to facilitate understanding.

1 is a conceptual diagram showing a liquefied gas regeneration system 100 according to an embodiment of the present invention.

Referring to FIG. 1, a liquefied gas regeneration system 100 according to an embodiment of the present invention includes a regasification line 110 for supplying a liquefied gas to a customer 10, a liquefaction line 110 for transporting along a regasification line 110, A first heat exchanger 111 and a second heat exchanger 112 for exchanging heat between the gas and the heating medium, a suction drum 120 for accommodating the heating medium, a pressure pump 130 for pressing the heating medium of the suction drum 120, A first medium circulation line 140 for circulating the first heat medium among the heating medium pressured by the first heat exchanger 130 to the suction drum 120 through the first heat exchanger 111, A second medium circulation line 150 for circulating the second heat medium to the suction drum 120 through the second heat exchanger 112 and a second medium circulation line 150 for circulating the first heat medium of the first heat medium before entering the first heat exchanger 111, A second heater 155 for heat-exchanging the second heat medium with the seawater before entering the second heat exchanger 112 of the second heat medium, A pressure regulating device 160 for regulating the supply amount and the degree of pressure reduction, a pressure maintaining device for maintaining the pressure of the second heat medium entering the second heat exchanger 112 by the regeneration line 110 at a predetermined pressure level or higher, And a seawater circulation line 190 for supplying and circulating the seawater to the first heater 145 and the second heater 155, respectively.

In the following examples, liquefied natural gas and regenerated natural gas are used as an example to help understand the present invention. However, the present invention is not limited thereto, and various liquefied gases such as liquefied ethane gas and liquefied hydrocarbon gas, Even if the regasified vaporized gas is applied thereto, the same technical idea should be equally understood.

The regasification line 110 is provided to regenerate the liquefied natural gas into natural gas and supply the natural gas to the consumer 10. The regeneration line 110 receives the liquefied natural gas from the storage tank 1 containing the liquefied natural gas by a delivery pump (not shown) or the like and receives the first heat exchanger 111 and the second heat exchanger 112 And can be supplied to the customer 10 after being regenerated and heated up in sequence. To this end, the inlet side end of the regasification line 110 is connected to a storage tank 1 for receiving liquefied natural gas, and the outlet side end can be connected to a consumer 10 requiring natural gas.

The storage tank (1) is installed in a floating structure and can be provided with heat insulation to stably receive liquefied natural gas and minimize external heat infiltration. The customer (10) A consumer who wants to consume natural gas, or various engines that use natural gas as a fuel gas. However, the present invention is not limited to this, and includes a case of a facility of various structures and systems. A temperature sensor T of a vaporizing gas temperature regulating device, which will be described later, may be provided at a rear end of the first heat exchanger 111 and the second heat exchanger 112, which are sequentially disposed on the regeneration line 110, A detailed description will be given later.

The first heat exchanger 111 and the second heat exchanger 112 heat-exchange the liquefied natural gas and the heating medium sequentially transferred along the regasification line 110 to regenerate the liquefied natural gas into natural gas, The temperature of the natural gas required by the engine 10 is increased. The first heat exchanger 111 is connected to the first natural gas recirculation line 110 via the suction natural gas and the suction drum 120, the pressurizing pump 130 and the first medium circulation line 140, By exchanging the heat medium with each other, the liquefied natural gas can be raised to about -50 to -10 degrees Celsius to regenerate the liquefied natural gas into low temperature natural gas. The second heat exchanger 112 passes through the first heat exchanger 111 on the regeneration line 110 to regenerate the low temperature natural gas and the suction drum 120, the pressure pump 130 and the second medium Temperature natural gas can be raised to a level corresponding to the natural gas temperature condition required by the customer 10 by exchanging heat between the second heat medium heated in the liquid state via the circulation line 150 with each other.

The suction drum 120 is provided to temporarily receive the heating medium, and the pressurizing pump 130 is provided to supply the heating medium from the suction drum 120 to pressurize and circulate the heating medium.

The suction drum 120 is conveyed along the first media circulation line 140 and the second media circulation line 150 and is conveyed through the first heat exchanger 111 and the second heat exchanger 112, And the second heating medium is temporarily supplied to the pressurizing pump 130. The liquid heating medium in the accommodated heat medium may be supplied to the pressurizing pump 130 through the medium supply line 125. [ As will be described later, since the first heat medium and the second heat medium, which pass through the first heat exchanger 111 and the second heat exchanger 112 respectively and are recovered to the suction drum 120, may have different pressures, The first heat medium and the second heat medium having different pressures are received and temporarily accommodated so as to cancel the pressure difference between the two heat mediums and simultaneously supply the heat medium to the pressurizing pump 130 by the internal pressure of the first heat medium and the second heat medium. have.

Generally, the pressurizing pump 130 is provided to prevent a malfunction and a failure, and to operate by receiving only a liquid heating medium for stable pressurization of the heating medium. The inlet side end of the medium supply line 125 is connected to the lower side of the suction drum 120 so that only the liquid heating medium can be supplied to the pressure pump 130. A pressurizing pump 130 is provided at a middle portion of the medium supply line 125 and an outlet end is provided to branch the first medium circulation line 140 and the second medium circulation line 150, The first heating medium and the second heating medium are branched and supplied to the first medium circulation line 140 and the second medium circulation line 150, respectively, after the heating medium conveyed along the first medium circulation line 125 is pressurized by the pressurization pump 130, .

The pressurizing pump 130 may supply the liquid heating medium stored in the suction drum 120 and pressurize the heating medium to perform effective heat exchange with the seawater and the liquefied natural gas. The pressurizing pump 130 is provided to press the heating medium such that the second heating medium entering the second heat exchanger 112 on the second medium circulation line 150 to be described later has a pressure condition of 6.54 barg or more in pressing the heating medium . On the other hand, the second heating medium conveyed along the second medium circulation line 150 can be lowered by a predetermined pressure while passing through the temperature control valve 180 and the second heater 155 described later. Therefore, For example, to a pressure level of about 9 barg. However, the pressurizing pressure of the pressurizing pump 130 is not limited to the value of about 9 barg, and the heat medium may perform the effective heat exchange of the seawater and the liquefied natural gas while the second heat medium may be supplied to the second heater 155 And includes a case where the refrigerant is pressurized to various ranges of pressure levels if it is at a pressure level capable of performing heat exchange without phase change in the second heat exchanger 112 while being heated in a liquid state without being vaporized even if heated. A detailed description thereof will be described later.

The heating medium can be made of a condensed heat transfer medium which can easily change phase between vapor and liquid phase. For example, the heating medium may be made of propane, which is easy to obtain from the cost side and can easily control the phase change between gas phase and liquid phase. However, the present invention is equally applicable to a case in which the phase change between the gas and the liquid phase is easy, and the liquid state can be maintained even if heated under a certain pressure range.

The first medium circulation line 140 is provided to circulate the first heat medium, which is a part of the heating medium pressurized by the pressurizing pump 130, to the first heat exchanger 111 side.

The first media circulation line 140 is branched from the rear end of the pressurization pump 130 on the medium supply line 125 with a second media circulation line 150 which will be described later, (Not shown). In addition, a first heater 145 for heating the first heat medium by heat exchange with the seawater is provided at the front end of the first heat exchanger 111 on the first medium circulation line 140, and a flow rate control A valve 160 may be provided.

The flow rate control valve 160 may be provided to regulate the supply amount and the pressure reduction degree of the first heat medium flowing into the first medium circulation line 140 among the heating mediums pressurized by the pressurization pump 130. The flow rate control valve 160 can reduce the pressure of the first heat medium to the pressure level at which the first heat medium introduced into the first medium circulation line 140 can be vaporized in heat exchange and heating in the first heater 145 . For example, when the heating medium is pressurized by the pressurizing pump 130 to a pressure level of about 9 barg, the flow regulating valve 160 reduces the pressure of the first heating medium to a pressure level of about 3 barg, 145 and is heat and vaporized by heat exchange with seawater and can be re-liquefied by heat exchange with the liquefied natural gas in the first heat exchanger 111 and recovered to the suction drum 120. However, in order to facilitate understanding of the present invention, for example, the numerical value may be set such that the first heating medium is vaporized by the heat exchange in the first heater 145, and at the same time, the pressure capable of being re-liquefied by heat exchange in the first heat exchanger 111 The pressure is reduced to a wide range of pressure levels.

The flow rate control valve 160 controls the flow rate of the pressurized fluid supplied from the suction drum 120 to the pressure pump 130 through the first heat exchanger 111, And the temperature information of the heating medium.

The suction drum 120 may be provided with a pressure sensor P for sensing the pressure of the heat medium contained in the suction drum 120. A suction pump 120 is connected to the front end of the pressure pump 130 on the medium supply line 125, A temperature sensor T for sensing the temperature of the heating medium supplied to the heating unit 130 may be provided. A temperature sensor T for sensing the temperature of the first heat medium having passed through the first heat exchanger 111 may be provided at the downstream end of the first heat exchanger 111 on the first medium circulation line 140.

When the temperature of the first heat medium, which has passed through the first heat exchanger 111 and has undergone the heat exchange with the liquefied natural gas, is lower than a predetermined temperature condition, the flow rate control valve 160 controls the internal pressure of the suction drum 120 When the temperature of the liquid heating medium supplied from the suction drum 120 to the pressurizing pump 130 is lower than the preset temperature condition, the supply amount of the first heat medium flowing into the first medium circulation line 140 As shown in Fig. When the temperature of the first heat medium which has passed through the first heat exchanger 111 and has been heat-exchanged with the liquefied natural gas is lower than a preset temperature condition, due to a shortage of the supply amount of the first heat medium entering the first heat exchanger 111, There is a possibility that sufficient heat transfer with the gas is not performed or heat exchange between the first heat medium and the liquefied natural gas is not effectively performed. The flow rate control valve 160 is connected to the first medium circulation line 111 so that the amount of heat transferred from the first heat medium to the liquefied natural gas is increased for stable temperature rise and regeneration by sufficient heat exchange of the liquefied natural gas in the first heat exchanger 111. [ The amount of the supply of the first heat medium flowing into the heat exchanger 140 may be increased. When the internal pressure of the suction drum 120 is lower than the predetermined pressure condition in the same context and the temperature of the liquid heating medium supplied from the suction drum 120 to the pressure pump 130 is lower than the predetermined temperature condition, There is a possibility that sufficient heat transfer with the liquefied natural gas is not performed due to insufficient supply of the first heat medium entering the first heat exchanger 111 or heat exchange between the first heat medium and the liquefied natural gas is not effectively performed, The flow control valve 160 may be operated in a direction to increase the supply amount of the first heat medium flowing into the first medium circulation line 140 such that the amount of heat transferred from the heat medium to the liquefied natural gas increases.

On the other hand, when the temperature of the first heat medium, which has passed through the first heat exchanger 111 and has undergone the heat exchange with the liquefied natural gas, is higher than a predetermined temperature condition, The temperature of the liquid heating medium supplied from the suction drum 120 to the pressurizing pump 130 is higher than the predetermined temperature condition, the first medium circulation line 140, And can be operated in a direction to reduce the supply amount of the heating medium. When the temperature of the first heat medium which has passed through the first heat exchanger 111 and has been heat-exchanged with the liquefied natural gas is higher than a preset temperature condition, the supply amount of the first heat medium entering the first heat exchanger 111 is excessive, Circulation or flow may be performed inefficiently. In order to reduce the amount of heat transferred from the first heating medium to the liquefied natural gas in order to efficiently operate the heating medium and the equipment, the flow control valve 160 controls the amount of the first heating medium flowing in the first medium circulation line 140 Lt; / RTI > When the internal pressure of the suction drum 120 is higher than a preset pressure condition in the same context and the temperature of the liquid heating medium supplied from the suction drum 120 to the pressure pump 130 is higher than a predetermined temperature condition, There is a risk of inefficient operation of the heating medium and equipment due to an excessive supply amount of the first heating medium flowing into the first heat exchanger 111, so that the flow rate control valve 160 is controlled so that the amount of heat transferred from the first heating medium to the liquefied natural gas decreases. 1 < / RTI > media circulation line < RTI ID = 0.0 > 140 < / RTI >

The first heater 145 is disposed between the downstream end of the flow control valve 160 and the upstream end of the first heat exchanger 111 on the first medium circulation line 140 and is connected to the first medium circulation line 140, Exchanges heat with seawater and is heated. The first heater 145 may vaporize the first heating medium by exchanging heat between the first heating medium, which is partially decompressed, through the flow control valve 160 and the seawater introduced through the seawater circulation line 190, which will be described later.

The first heat exchanger 111 is provided between the first medium circulation line 140 and the regasification line 110 and is supplied to the first medium circulation line 140 through the first heater 145, And the liquefied natural gas transferred along the regasification line 110 to each other. The liquefied natural gas transferred along the regasification line 110 receives heat from the vaporized first heat medium while passing through the first heat exchanger 111 and is heated to a temperature range of about -50 to -10 degrees Celsius, The first heat medium, which is conveyed along the first medium circulation line 140, passes through the first heat exchanger 111 and flows through the first heat exchanger 111 to the cryogenic liquefied natural gas And can be re-liquefied in a liquid state by heat exchange. The first heat medium having passed through the first heat exchanger 111 can be conveyed along the first medium circulation line 140 and can be recovered to the suction drum 120 and can be recovered through the medium supply line 125 And may be re-supplied to the first medium circulation line 140 or the second medium circulation line 150 by being re-supplied to the pressurizing pump 130. [

The second medium circulation line 150 is a part of the heating medium which is supplied to the first medium circulation line 140 among the heating mediums pressurized by the pressurizing pump 130, And circulates the second heat medium, which is a heat medium, to the second heat exchanger 112 side.

The second media circulation line 150 is provided such that the inlet side end is branched from the rear end of the pressurizing pump 130 on the medium supply line 125 together with the inlet side end of the first medium circulation line 140, And may be connected to the inside of the suction drum 120. The second heat exchanger 112 may be provided at the front end of the second heat exchanger 112 on the second medium circulation line 150 to heat the second heat medium by exchanging heat with the seawater. A pressure holding device may be provided to maintain the pressure of the entering second heat medium at a predetermined range or more.

The second heater 155 is provided at the upstream side of the second heat exchanger 112 on the second medium circulation line 150 and is adapted to heat the second heat medium flowing into the second medium circulation line 150 by heat exchange with seawater . The second heater 155 heats the second heating medium, which has passed through the low-temperature second heating medium and the seawater circulating line 190, to the second heat exchanger 112 Can supply.

In the case of the second heat exchanger provided in the conventional regeneration system, in order to raise natural gas at a low heat medium circulation flow rate during heat exchange between the liquefied natural gas and the heat medium, the heat medium is vaporized through heat exchange with seawater, Heat exchanged. However, in this case, since the heating medium must be heated to the vaporization temperature in order to vaporize the heating medium, there is a problem that it is difficult to heat the heating medium only by the seawater itself. In recent years, as a design condition of the liquefied gas regeneration system, it is required to design the seawater temperature to be at least 14 degrees Celsius and the vaporized gas supplied to the customer, that is, the natural gas temperature to be 8 degrees Celsius. When the conventional second heat exchanger is operated, as shown in FIG. 2, a temperature interval in which heat exchange is practically difficult to be realized is formed, so that the actual operation of the regeneration system is impossible.

FIG. 2 is a graph showing a result of simulating a temperature change of a natural gas, a heating medium and seawater according to a pressure of a heating medium in a conventional second heat exchanger. The graph x axis of FIG. 2 represents the heat flow per unit time or unit cross-sectional area, and the graph y axis represents the Celsius temperature.

Referring to FIG. 2, the heating medium supplied to the conventional second heat exchanger must be vaporized by heat exchange with the water before heat exchange in the second heat exchanger. In the second heat exchanger, . When the heat medium is composed of propane with a pressure level of 5.5 barg, the heat medium is heated by heat exchange with seawater, and when the temperature changes from liquid phase to vapor phase at about -5 ° C., In this case, the heat medium absorbs the heat of seawater as latent heat and there is no change in temperature. As a result, a temperature reversal occurs in which the temperature of propane, which is a heat medium, becomes lower than the temperature of natural gas, There is a problem that the temperature of natural gas can not be raised.

On the contrary, when the heating medium is composed of propane having a pressure level of 6.5 barg, the heating medium is heated by heat exchange with seawater, and a phase change from a liquid state to a vapor state occurs at about 10 degrees Celsius, There is a problem in that heat exchange occurs between the heat medium and the sea water due to the temperature reversal which occurs when the temperature of propane, which is a heating medium, is higher than the temperature of the seawater.

As another example, when the heating medium is made of propane having a pressure level of 6.0 barg, the heating medium is heated by heat exchange with the sea water according to the graph of FIG. 2, and the temperature of the heating medium is changed from the liquid state to the vapor state at a temperature close to the sea water temperature As the change takes place, it absorbs the heat of the seawater, and although it is close to the temperature of the natural gas, it has a finely high temperature, so theoretically, heat exchange between the natural gas and the heat medium is possible. However, in reality, when the temperature difference between the two media performing heat exchange in the heat exchanger is less than 0.5 degrees Celsius as in the third and the fourth intervals of FIG. 2, heat exchange between the two media is practically not realized. It is impossible to apply it to the actual regeneration system.

That is, when the temperature rise of the natural gas is attempted by utilizing the latent heat of the heating medium as in the case of the conventional second heat exchanger, the temperature difference between the heating medium and the sea water or between the heating medium and the natural gas occurs, , Heat exchange between the heat medium and the natural gas can not be performed. This problem is solved and the performance and reliability of the liquefied natural gas regeneration process is improved through stable and effective heat exchange between the heat medium and the sea water, and the heat medium and the natural gas A solution is required.

FIG. 3 is a graph showing changes in temperature of natural gas, heat medium and seawater in the second heat exchanger 112 according to the embodiment of the present invention. Specifically, Gas, heat medium and sea water.

3, when the second heat medium entering the second heat exchanger 112 is made of propane having a pressure level of 6.54 barg, even if the second heat medium is heat-exchanged with the seawater in the second heater 155, And the second heat exchanger 112 can also perform heat exchange in a liquid state without phase change.

Specifically, when the second heating medium, which is conveyed along the second medium circulation line 150 and before entering the second heat exchanger 112, has a pressure level of 6.54 barg, the second heating medium flows from the second heater 155 The temperature can be linearly increased during heating due to heat exchange with the seawater. Accordingly, since the temperature is lower than the seawater temperature in the graph of FIG. 3, heat exchange between the second heat medium and the seawater can be effectively realized in the second heater 155 . At the same time, since the second heat medium is higher in temperature than the natural gas in the graph of FIG. 3, the heat exchange between the second heat medium and the natural gas in the second heat exchanger 112 can be effectively realized.

In the practical application of the liquefied gas regeneration system 100 of the present invention, the second heat medium introduced into the second medium circulation line 150 is supplied to the temperature control valve 180 of the vaporization gas temperature regulator, The pressure pump 130 may pressurize the second heat medium pressure condition before entering the second heat exchanger 112 so as to have a pressure of 6.54 barg or more.

Hereinafter, the second heat medium requires a pressure value of 6.54 barg or more. Table 1 below shows the temperature change (Temparature) of the second heat medium with respect to the heat flow when the pressure of the second heat medium is 6.53 barg. Table 2 shows the temperature change Of the second heating medium.

In Table 1, when the pressure of the second heat medium entering the second heat exchanger 112 is 6.53 barg, the temperature of the second heat medium is increased by heat exchange with seawater in the second heater 155, A phase change occurs and a constant temperature is generated. Accordingly, when the pressure of the second heat medium entering the second heat exchanger 112 corresponds to 6.53 barg, the heating medium in FIG. 2 described above is formed into a graph having the same shape as that of the propane having the pressure level of 6.5 barg , A phase inversion occurs in which the temperature of the second heat medium becomes higher than the temperature of the seawater while a phase change occurs at about 10 degrees Celsius.

On the other hand, referring to Table 2, when the pressure of the second heat medium entering the second heat exchanger 112 is 6.54 barg, the second heater 155 can be heated to a liquid state without phase change during heat exchange with seawater At the same time, heat exchange is performed in the second heat exchanger 112 without a phase change, and the temperature change of the second heat medium with respect to heat flow appears linearly. Accordingly, heat exchange between the second heat medium and the seawater in the second heater 155 and between the second heat medium and the natural gas in the second heat exchanger 112 can be effectively implemented, and the liquefied natural gas The regeneration and the temperature rise can be stably performed. Accordingly, the pressurizing pump 130 pressurizes the heating medium such that the second heating medium entering the second heat exchanger 112 has a pressure of 6.54 barg or more so that the second heating medium maintains a liquid phase state during heat exchange in the second heat exchanger 112. [ And a pressure holding device to be described later may be provided to maintain the pressure of the second heat medium entering the second heat exchanger 112 at 6.54 barg or more.

Meanwhile, in Table 2, it is required that the temperature condition of the second heat medium is set to about 11 degrees Celsius so that the minimum temperature difference between the two media is at least about 3 degrees Celsius for efficient heat exchange between the two media during operation of the actual heat exchanger. As described above, considering the design conditions of the liquefied gas regeneration system 100, the sea water temperature and the natural gas temperature must be designed to 14 degrees Celsius and 8 degrees Celsius, respectively, And a temperature difference of about 3 degrees is provided to realize effective heat exchange in the second heater 155 and the second heat exchanger 112. [

The second heat exchanger 112 is provided between the second media circulation line 150 and the regasification line 110 and is provided at the rear end of the first heat exchanger 111 on the regasification line 110, The second heat medium passing through the second heater 155 on the circulation line 150 and heated in the liquid state is conveyed along the regeneration line 110 and passes through the first heat exchanger 111 to regenerate the natural gas Are exchanged with each other. Natural gas entering the second heat exchanger 112 on the regasification line 110 passes through the second heater 155, receives heat from the heated second heat medium, and is heated to be supplied to the customer 10 . At the same time, the second heating medium conveyed along the second medium circulation line 150 can be cooled without phase change, conveyed along the second medium circulation line 150 and recovered to the suction drum 120, May be re-supplied to the pressurization pump 130 through the first medium circulation line 125 or the second medium circulation line 150 to be recycled to the first medium circulation line 140 or the second medium circulation line 150.

The pressure holding device is provided to maintain the pressure of the second heat medium entering the second heat exchanger 112 at 6.54 barg or more. The pressure holding device includes a pressure sensor P for detecting the pressure of the second heat medium entering the second heat exchanger 112 and a pressure sensor P for detecting the pressure of the second heat medium flowing through the second heat exchanger 112 on the second medium circulation line 150. [ A valve 170 may be included.

As described above, when the pressurizing pump 130 presses the heating medium, the pressure of the second heating medium entering the second heat exchanger 112 is pressurized to have a pressure of 6.54 barg or more. In reality, the second heating medium is pressurized by the vaporizing gas There is a possibility that a predetermined pressure drop occurs when passing through the temperature regulating valve 180 and the second heater 155 of the temperature regulating device. Particularly, the temperature of the seawater can be variously changed according to the environmental conditions of the sea area in which the liquefied gas regeneration system 100 is operated. As the temperature of the seawater supplied to the second heater 155 changes, There is a possibility that the pressure of the second heating medium entering the heating medium 112 may not be maintained at a certain level.

The pressure holding device senses the pressure of the second heat medium entering the second heat exchanger 112 by the pressure sensor P and controls the second heat exchanger 112 on the second medium circulation line 150, The pressure of the second heat medium in the second heat exchanger 112 can be maintained at 6.54 barg or more by controlling the degree of opening and closing of the pressure regulating valve 170 provided at the rear end. The pressure sensor P is provided on the second medium circulation line 150 at the upstream end of the second heat exchanger 112 and is connected to the second heat exchanger 112 through the second heater 155, And the pressure regulating valve 170 is installed between the rear end of the second heat exchanger 112 and the suction drum 120 on the second medium circulation line 150, And can be controlled to operate based on the pressure information of the heating medium.

For example, when the pressure of the second heat medium entering the second heat exchanger 112 sensed by the pressure sensor P is less than 6.54 barg, heat exchange is smooth in the second heat exchanger 155 and the second heat exchanger 112 It is possible to raise and maintain the pressure of the second heat medium on the second medium circulation line 150 by operating in the direction of closing the pressure regulating valve 170. [ On the other hand, when the pressure of the second heat medium entering the second heat exchanger 112 sensed by the pressure sensor P is 6.54 barg or more, the second medium circulation line 150 and the second heater 155 The pressure of the second heat medium on the second medium circulation line 150 is lower than the pressure of the second heat medium on the second medium circulation line 150. Therefore, It is possible to reduce the pressure of the second heating medium in the direction approaching 6.54 barg.

The vaporizing gas temperature regulator is provided to regulate the temperature of the regenerated vaporized gas, that is, the natural gas, through the first heat exchanger 111 and the second heat exchanger 112 on the re-oxidation line 110. The vaporization gas temperature regulating device includes a temperature sensor (T) for sensing the temperature of the natural gas regenerated by the regeneration line (110) and a temperature sensor (T) for regulating the supply amount of the second heat medium flowing into the second medium circulation line A control valve 180 may be included.

As described above, since the temperature of the seawater can be variously changed according to the environmental conditions of the sea area in which the liquefied gas regeneration system 100 is operated, the first heat exchanger 111 and the second heat exchanger 112 The temperature of the regasified natural gas may be lower than the temperature condition required by the customer 10.

A temperature sensor T is provided at the downstream of the first heat exchanger 111 and the second heat exchanger 112 on the regeneration line 110 so as to pass through the first heat exchanger 111 and the second heat exchanger 112 And controls the degree of opening and closing of the temperature control valve 180 provided on the upstream side of the second heater 155 on the second medium circulation line 150 based on the detected temperature of the natural gas, ) Can be adjusted to about 8 degrees Celsius.

For example, when the temperature of the natural gas sensed by the temperature sensor T is less than about 8 degrees Celsius, the temperature control valve 180 may increase the supply amount of the second heat medium flowing into the second medium circulation line 150 The amount of heat transferred to the natural gas in the second heat exchanger 112 is increased and the temperature of the natural gas supplied to the consumer 10 through the second heat exchanger 112 is requested by the customer 10 It can be raised to a level corresponding to the temperature condition. On the contrary, when the temperature of the natural gas sensed by the temperature sensor T is equal to or higher than about 8 degrees Celsius, the temperature control valve 180 moves in the direction of decreasing the supply amount of the second heat medium flowing into the second medium circulation line 150 It is possible to lower the temperature of the natural gas supplied to the customer 10 to a level corresponding to the temperature condition required by the customer 10. [ Alternatively, when the temperature of the natural gas detected by the temperature sensor T corresponds to about 8 degrees Celsius, the temperature control valve 180 maintains the supply amount of the second heat medium flowing into the second medium circulation line 150 In the direction of the arrow.

The seawater circulation line 190 is provided to supply and circulate seawater to the first heater 145 and the second heater 155, respectively.

The seawater circulation line 190 may be provided with a seawater pump 191 for circulating the seawater and a heater for auxiliary heating the seawater. The seawater pump 191 circulates the seawater in the vicinity of the floating marine structure on which the liquefied gas regeneration system 100 is mounted to the first heater 145 and the second heater 155 along the seawater circulation line 190 .

The heater includes a first heater 192 for heating the seawater supplied to the second heater 155 along the seawater circulation line 190 and a second heater 193 for heating the seawater supplied to the first heater 145 . The first heater 192 is disposed upstream of the second heater 155 on the seawater circulation line 190. When the temperature of the seawater is low during the heat exchange between the seawater and the second heating medium conveyed along the second medium circulation line 150 In the case where it is difficult to smoothly perform the heat exchange in the second heat exchanger 112, the seawater can be supplementarily heated and supplied to the second heat exchanger 112 side. Likewise, the second heater 193 is disposed on the seawater circulation line 190 at the upstream side of the first heater 145, and when the heat exchange between the seawater and the second heating medium conveyed along the first medium circulation line 140, The seawater can be supplementarily heated to be supplied to the second heat exchanger 112 side when heat exchange in the first heat exchanger 111 is difficult to achieve smoothly.

The first heater 192 and the second heater 193 may be formed of a heat exchanger. The heat medium such as glycol water may receive heat from the engine waste heat of the boiler or the floating structure, The first heater 192 and the second heater 193 to heat the seawater to supplementarily heat the seawater.

Hereinafter, a liquefied gas regeneration system 200 according to another embodiment of the present invention will be described.

FIG. 4 is a conceptual view illustrating a liquefied gas regeneration system 200 according to another embodiment of the present invention. Referring to FIG. 4, a liquefied gas regeneration system 200 according to another embodiment of the present invention includes liquefied gas A first heat exchanger 111 and a second heat exchanger 112 for exchanging heat between the liquefied gas conveyed along the regasification line 110 and the heating medium, A pressurizing pump 130 for pressurizing the heating medium of the suction drum 120 and a first heating medium of the heating medium pressed by the pressurizing pump 130 are connected to the suction drum 120 via the first heat exchanger 111, A second medium circulation line 140 for circulating the second heat medium in the heating medium pressurized by the pressurizing pump 130 to the suction drum 120 via the second heat exchanger 112, A line 150, a first heater 145 for heat-exchanging the first heat medium with the seawater before entering the first heat exchanger 111, A second heater 155 for heat-exchanging the second heat medium with seawater before entering the second heat exchanger 112 of the second heat medium, a flow control valve 160 for regulating the supply amount of the first heat medium and the degree of pressure reduction, A pressure holding device for maintaining the pressure of the second heat medium entering the second heat exchanger (112) at a predetermined pressure level or higher, a vaporizing gas temperature control device for regulating the temperature of the regenerated vaporized gas, And a seawater circulation line 290 for supplying and recirculating the first and second heaters 145 and 145 to the first heater 145 and the second heater 155, respectively.

The liquefied gas regeneration system 200 according to another embodiment of the present invention will now be described with reference to the accompanying drawings. In the liquefied gas regeneration system 200 according to an embodiment of the present invention, 100, and description thereof will be omitted in order to avoid duplication of contents.

The sea water circulation line 290 of the liquefied gas regeneration system 200 according to another embodiment of the present invention is provided to supply and recycle seawater to the first heater 145 and the second heater 155 respectively.

The seawater circulation line 290 includes a seawater pump 191 for circulating the seawater, a heater for heating the seawater auxiliaryly, a seawater intake valve 291 for regulating the inflow of the seawater into the seawater circulation line 290, A seawater discharge valve 292 for controlling whether or not the seawater is discharged from the seawater circulation line 290 of the seawater and the seawater discharged from the first heater 145 or the second A recirculation line 293 for re-feeding to the heater 155 side, and a recirculation valve 294 provided in the recirculation line 293.

 The seawater intake valve 291 is provided at a front end of the seawater pump 191 on the seawater circulation line 290 and can control the inflow of seawater into the seawater circulation line 290. The seawater discharge valve 292 is provided at the rear end of the point where the seawater passing through the first heater 145 and the second heater 155 respectively join together to control whether the seawater is discharged from the seawater circulation line 290. The recirculation line 293 is provided so that its inlet end is connected to the rear end of the point where the seawater passing through the first heater 145 and the second heater 155 respectively join and the front end of the seawater discharge valve 292, The side end portion is provided so as to join between the front end of the seawater pump 191 on the seawater circulation line 290 and the rear end of the seawater suction valve 291 so that the seawater having passed through the first heater 145 or the second heater 155, And is supplied again to the first heater 145 or the second heater 155 without being discharged from the circulation line 290.

If the temperature of the seawater sensed by the seawater temperature sensor (not shown) is very low, the first heater 145 and the second heater 155 may not smoothly implement the heating process of the first heating medium and the second heating medium At this time, when the first heater 192 and the second heater 193 are continuously operated or the output is increased for heating the seawater, additional energy is required, resulting in inefficient facility operation. Therefore, when the temperature of the seawater is very low, the seawater intake valve 291 and the seawater discharge valve 292 are closed, the recirculation valve 294 provided in the recirculation line 293 is opened, and the seawater circulation line 290 is opened The reclaimed seawater can be recycled through the recycle line 293.

The temperature of the seawater supplied to the first heater 145 and the second heater 155 can be maintained within a predetermined range despite various temperature conditions of the seawater according to the environmental conditions of the sea area in which the liquefied gas regeneration system 200 is operated It is possible to improve the performance of the liquefied natural gas regeneration system and the reliability of the process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of the invention should be determined only by the appended claims.

100, 200: liquefied gas regeneration system
110: regeneration line 111: first heat exchanger
112: second heat exchanger 120: suction drum
130: pressure pump 140: first media circulation line
145: first heater 150: second medium circulation line
155: Second heater 160: Flow regulating valve
170: Pressure maintaining valve 180: Temperature control valve
190, 290: Seawater circulation line 191: Seawater pump
192: first heater 193: second heater
291: Seawater intake valve 292: Seawater discharge valve
293: recirculation line 294: recirculation valve

Claims (10)

A regasification line for regenerating liquefied gas and supplying it to a customer;
A first heat exchanger and a second heat exchanger sequentially exchanging heat between the liquefied gas and the heat medium transferred along the regasification line;
A suction drum for accommodating the heating medium;
A pressurizing pump for pressurizing the heating medium of the suction drum;
A first medium circulation line for circulating the first heat medium among the heating medium pressurized by the pressurizing pump to the suction drum via the first heat exchanger;
A second medium circulation line for circulating the second heat medium of the heating medium pressurized by the pressurizing pump to the suction drum via the second heat exchanger;
A first heater provided at a front end of the first heat exchanger on the first medium circulation line for heat-exchanging the first heat medium with seawater; And
And a second heater provided at a front end of the second heat exchanger on the second medium circulation line for heat-exchanging the second heat medium with seawater,
Wherein the heating medium is made of propane,
The first heat medium is vaporized by the first heater and then re-liquefied and heat-exchanged in the first heat exchanger, and the second heat medium is heated in a liquid state by the second heater, The pressurizing pump pressurizes the second heat medium entering the second heat exchanger to have a pressure of at least 6.54 barg to heat exchange. delete delete The method according to claim 1,
Further comprising a pressure holding device for maintaining the pressure of the second heat medium entering the second heat exchanger at 6.54 barg or more,
The pressure holding device
A pressure sensor for sensing a pressure of a second heat medium entering the second heat exchanger, and a pressure control valve provided at a rear end of the second heat exchanger on the second medium circulation line,
Wherein the operation of the pressure regulating valve is controlled based on pressure information of the second heat medium sensed by the pressure sensor. 5. The method of claim 4,
Further comprising a vaporizing gas temperature regulating device for regulating the temperature of the vaporized gas regenerated by said regeneration line,
The vaporizing gas temperature regulating device
A temperature sensor for sensing the temperature of the vaporized gas, and a temperature control valve for controlling the supply amount of the second heating medium,
Wherein the operation of the temperature regulating valve is controlled based on temperature information of the vaporized gas sensed by the temperature sensor. 6. The method of claim 5,
Further comprising a flow control valve for regulating a supply amount and a pressure reduction degree of the first heat medium,
The flow control valve
The operation is controlled based on at least one of temperature information of the first heat medium that has passed through the first heat exchanger and heat-exchanged, internal pressure information of the suction drum, and temperature information of the heat medium supplied from the suction drum to the pressure pump Liquefied gas regeneration system. 7. The method according to any one of claims 4 to 6,
Further comprising a seawater circulation line having a seawater pump to supply and circulate seawater to the first heater and the second heater, respectively. 8. The method of claim 7,
The seawater circulation line
And a heater for auxiliary heating the seawater. 9. The method of claim 8,
The heater
A first heater for heating seawater supplied to the second heater and a second heater for heating seawater supplied to the first heater. 10. The method of claim 9,
The seawater circulation line
A seawater discharge valve for regulating whether the seawater is discharged or not, and a seawater discharge valve for regulating the flow of seawater having passed through the first heater or the second heater to the first heater or the second heater And a recirculation valve provided in the recirculation line,
The seawater intake valve, the seawater discharge valve and the recirculation valve
A liquefied gas regasification system whose operation is controlled based on the temperature information of seawater.

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