KR20110087970A - Floating type lng regasification unit - Google Patents

Abstract

PURPOSE: A floating LNG re-gasification facility is provided to produce both gas and electricity by employing a gas turbine generator and drive the gas turbine generator using the gas produced by an LNG re-gasification unit. CONSTITUTION: A floating LNG re-gasification facility comprises an LNG storage tank(10), an LNG re-gasification unit(20), a gas turbine generator(30) which is activated by the re-gasified gas provided from the LNG re-gasification unit, and an exhaust gas heat exchanger(40) which generates steam using the exhaust gas produced in the gas turbine generator.

Description

Floating type LNG regasification unit

The present invention relates to a floating LNG regasification plant, and more specifically, by adding a gas turbine generator, which is a power production facility that can produce power on a regasification plant for regasifying an LENG, basically gas and electricity. It is possible to supply at the same time, and also to drive the gas turbine generator using the gas generated from the regasification plant, thereby eliminating the compressor for gas compression of the gas turbine generator to reduce the cost of installing the gas turbine generator In addition, by generating steam by using the exhaust gas generated from the gas turbine generator, it can be used as the driving power of the LENG gas regenerator and the steam turbine generator added for electric power generation, to the entire facility according to the waste heat recovery Energy can be minimized to reduce costs Doemeun course, it is through the use of waste heat in elenji floating regasification facility to be able to prevent marine pollution.

Generally, LNG Floater (LNG Floater Regasification Facility) refers to a marine facility having a facility for producing LNG or Natural Gas on a float in the form of a barge.

The LNG Floater has a different arrangement of the upper equipment depending on the shape of the cargo hold that stores the LG. For example, when the cargo hold is a moss (MOSS), there is no sloshing problem of LNG. Although it is recognized as safe, space constraints are required to produce FPSO (floating oil production storage) to produce LENG, or to convert existing LNG ship into LNG FPSO, which requires more area than necessary.

In addition, when the cargo hold is a membrane, there are many limitations in using it as a cargo hold of an LNG plotter due to the problem of slack, and in particular, the strength of the insulation portion of the cargo hold must be greatly increased, and also in the case of modification. Part of the cargo hold is to be changed and replaced with reinforced insulation material.

And, if the cargo hold is SPB (spb) is not expected to have a problem of slack, it is used as the cargo hold of the LENG Plotter, but the production cost compared to the membrane (Membrane) method.

As such, by using various LNG regasification facilities according to the shape of the cargo hold it is possible to produce gas in a floating state on the sea surface.

As an example, a brief look at the floating LNG regasification plant according to the prior art as follows.

As shown in Figure 1, the floating LENG regasification facility of the prior art is in the floating state on the sea, and each of the L NG tank 10 and the L ENG in which the L ENG tank 10 is discharged to the outside. Low pressure pump (81) to be made, a buffer tank (82) for firstly alleviating the L-engine discharged from the L-engine tank (10), and a high-pressure pump for discharging the L-engine of the buffer tank (83) to the outside ( 83), a flow control valve 84 for controlling the flow rate supply of the LENG, and the LENG regasifier 20 for regasifying the LENG.

The prior art of such a configuration is to produce the gas after the L engine is supplied from the L tank tank 10 to regasify the L engine in the L regasifier 20.

However, since the LG regasification facility of the prior art is capable of producing only gas and used sea water for regasification, it has an adverse effect on the marine environment, and also in the summer when the gas consumption is reduced. Longer storage periods result in energy wastage by forcibly incineration of gases generated by heat transfer or release to the atmosphere, and also in the case of generators used to support offshore plant construction. Due to this has caused problems such as marine pollution.

The present invention has been made to solve the above problems, by adding a gas turbine generator which is a power production equipment that can produce power on the regasification facility for regasification of the LENG, basically supplying gas and electricity at the same time The purpose is to provide a floating LNG regasification facility that can be enabled.

In addition, it is possible to drive the gas turbine generator using the gas generated from the regasification facility, the compressor for gas compression of the gas turbine generator is eliminated to reduce the cost associated with the gas turbine generator installation Another purpose is to provide fire-fighting equipment.

In addition, by generating steam by using the exhaust gas generated from the gas turbine generator can be used as the driving power of the LENG gas regenerator and steam turbine generator added for electric power generation, the energy required for the entire facility according to the waste heat recovery The aim of the present invention is to provide a floating LNG regasification facility that can minimize costs and reduce costs, as well as prevent marine pollution through the use of waste heat.

In order to achieve the above object, the floating LNG regasification plant of the present invention includes an LNG storage tank and an LNG regasifier, in which the LNG regasification facility comprises gas, as well as electric power through the LNG regasifier. Characterized in that it further comprises a power production equipment to produce a.

In addition, in the floating LNG regasification plant according to the present invention, it is preferable that the power production facility is to produce power through a gas turbine generator operated by the regasification gas produced in the LNG regasifier.

In addition, in the floating L engine regasification plant according to the present invention, it is preferable that the exhaust gas heat exchanger for generating a high-temperature steam using the exhaust gas generated in the gas turbine generator.

In addition, in the floating LNG regasification plant according to the present invention, it is preferable that the LNG regasifier uses steam generated by the exhaust gas heat exchanger as an energy source for LNG regasification.

In addition, in the floating LNG regasification plant according to the present invention, it is preferable that the steam through the LNG regasifier is converted into water and reused as condensate for steam generation in an exhaust gas heat exchanger.

In addition, in the floating LNG regasification plant according to the present invention, it is preferable that a heat exchanger for converting the water discharged from the LNG regasifier into hot condensate.

In addition, in the floating LNG regasification plant according to the present invention, the heat exchanger is a high-temperature cooling water discharged from the gas turbine generator or other air conditioning system on the regasification facility using the cooled water discharged from the LNG regasifier. It is preferable to use for cooling.

In addition, in the floating L engine regasification facility according to the present invention, it is preferable that a steam turbine generator for generating electricity by using steam generated in the exhaust gas heat exchanger is further provided.

In addition, in the floating LENG regasification plant according to the present invention, the water discharged from the steam turbine generator is preferably mixed with the water discharged from the LENG regasifier to be supplied to the heat exchanger.

In addition, in the floating LNG regasification plant according to the present invention, it is preferable that a supply passage for supplying the exhaust gas generated in the exhaust gas heat exchanger to the LNG regasifier.

As described above, the floating LNG regasification facility according to an embodiment of the present invention is basically by adding a gas turbine generator that is a power production facility that can produce power on the regasification facility for regasifying the LENG, The effect of being able to supply gas and electricity at the same time is obtained.

In addition, it is possible to drive the gas turbine generator using the gas generated from the regasification facility, the compressor for the gas compression of the gas turbine generator is eliminated to obtain the effect of reducing the cost of installing the gas turbine generator.

In addition, by generating steam using the exhaust gas generated from the gas turbine generator, it can be used as the driving power of the LENG gas regenerator and the steam turbine generator added for electric power generation, the energy required for the entire facility according to the waste heat recovery In addition, the cost savings can be minimized, and marine pollution can be prevented through the use of waste heat.

1 is a schematic view showing a floating LNG regasification plant according to the prior art.
Figure 2 is a schematic diagram showing a state in which the power production equipment is further provided in the floating LNG regasification equipment according to an embodiment of the present invention.

The present invention having the above configuration will be described in more detail with reference to the following drawings.

As shown in FIG. 2, the floating LNG regasification plant according to an embodiment of the present invention is configured to include an LNG storage tank 10, an LNG regasifier 20, and a power production facility capable of producing electric power. It is.

Here, the power production equipment is to produce power through the gas turbine generator 30 which is operated by the regasification gas produced by the LENG regasifier 20.

In addition, an exhaust gas heat exchanger 40 for generating high temperature steam using the exhaust gas generated by the gas turbine generator 30 is provided.

Here, the LNG regasifier 20 uses steam generated by the exhaust gas heat exchanger 40 as an energy source for regasification of the LNG.

The steam through the LNG regasifier 20 is converted into water and reused as condensate for steam generation in the exhaust gas heat exchanger 40.

A heat exchanger 50 is provided to cool the high temperature cooling water discharged from the gas turbine generator 30 or the air conditioning system on the regasification plant by using the water discharged from the LNG regasifier 20. .

Here, the heat obtained through the heat exchange of the heat exchanger 50 also serves to heat the water discharged from the LNG regasifier 20.

In addition, a steam turbine generator 60 for generating electricity using steam generated by the exhaust gas heat exchanger 40 is further provided as a power production equipment of the present invention.

The water discharged from the steam turbine generator 60 is mixed with the water discharged from the LNG regasifier 20 and supplied to the heat exchanger 50.

On the other hand, the supply passage 70 for supplying the exhaust gas generated in the exhaust gas heat exchanger to the LENG regasifier is further provided.

Reference numeral 81 denotes a low pressure pump in the L engine tank 10, 82 denotes a buffer tank, 83 denotes a high pressure pump, and 84 denotes a flow control valve.

In addition, reference numeral 85 denotes a gas flow meter, 86 denotes a distributor, 87 denotes a transformer, and 88 denotes a circulating pump.

Floating LNG regasification equipment according to an embodiment of the present invention according to this configuration is basically received from the LNG storage tank 10 through the low-pressure pump 81, the buffer tank 82 and the high-pressure pump (83) Gas is produced in the regasifier 20, and in addition to the installation of a power production equipment to be able to produce power.

Looking at the power production process through the above-described power production equipment, first, a gas turbine generator 30 is installed as the power production equipment and the gas turbine generator 30 through the regasification gas produced by the LNG regasifier 20. To generate power.

Here, the exhaust gas generated in the gas turbine generator 30 generates steam through heat exchange with condensate in the exhaust gas heat exchanger 40 and is then discharged to the atmosphere.

In addition, the high temperature steam obtained through the heat exchange is used as an energy source for the LNG regasification of the LNG regasifier 20.

That is, from this time, the LNG regasifier 20 may operate using steam generated in the exhaust gas heat exchanger 40 without using diesel, which is a starting fuel.

The steam through the LNG regasifier 20 is converted into water and reused as condensate for steam generation in the exhaust gas heat exchanger 40.

At this time, the steam passed through the LNG reflow machine 20 is converted to water (about 20 ℃) is sent to the heat exchanger (50). Then, the high temperature coolant is exchanged with the high temperature (approximately 60 ° C.) cooling water discharged from the gas turbine generator 30 or other air conditioning system on the regasification plant, and the like. ) Into coolant such as the gas turbine generator 30 or the air conditioning system on the regasification plant.

On the other hand, a part of the steam generated in the exhaust gas heat exchanger 40 is sent to the steam turbine generator 60 for generating electricity to generate electricity.

The water discharged from the steam turbine generator 60 (approximately 40 ° C.) is mixed with the water discharged from the LENG regasifier 20 and supplied to the heat exchanger 50.

At this time, the water heat exchanged in the heat exchanger 50 is approximately 45 ~ 50 ℃ degree is sent to the exhaust gas heat exchanger 40 as the condensed water through the circulation pump (88).

Meanwhile, the exhaust gas discharged from the exhaust gas heat exchanger 40 may be supplied to the LENG regasifier 20 again through a separate supply passage 70.

As described above, the present invention can produce gas through the LNG regasifier 20 and at the same time, it is possible to generate electricity by driving the gas turbine generator 30 by using the gas which is regasified. By making steam using the exhaust gas of the generator 30, it can be used as a driving raw material of the LNG vaporizer 20 and the steam turbine generator 60, so that various effects such as efficient energy utilization and prevention of marine pollution can be obtained. Will be.

In the above described a preferred embodiment of the present invention, but described in the claims and detailed description of the present invention as well as the embodiment of the present invention simply applied in combination with the known art of the present invention to those skilled in the art It is to be understood that the description of the degree to which the present invention can be simply modified is included in the technical scope of the present invention.

** Description of symbols for the main parts of the drawing **
10: LNG tank 20: LNG vaporizer
30 gas turbine generator 40 exhaust gas heat exchanger
50: heat exchanger 60: steam turbine generator
70: supply flow path 81: low pressure pump
82: buffer tank 83: high pressure pump
84: flow control valve 85: gas flow meter
86: distributor 87: transformer
88: circulation pump

Claims (10)

In the floating LENG regasification facility comprising an LNG storage tank 10 and the LNG regasifier 20,
Floating LNG regasification facility, characterized in that it further comprises a power production facility for producing gas as well as the production of gas through the LNG regasifier (20). The method of claim 1,
The power production facility is a floating LNG regasification facility, characterized in that to produce power through a gas turbine generator 30 is operated by the regasification gas produced in the LNG regasifier (20). The method of claim 2,
Floating LNG regasification facility, characterized in that the exhaust gas heat exchanger 40 for generating high-temperature steam using the exhaust gas generated in the gas turbine generator 30 is further provided. The method of claim 3,
The LNG regasifier 20 is a floating LNG regasification facility, characterized in that to use the steam generated in the exhaust gas heat exchanger 40 as an energy source for the regasification of the LENG. The method of claim 4, wherein
The steam through the LNG regasifier 20 is converted into water and is again reused as condensed water for steam generation in the exhaust gas heat exchanger (40). The method of claim 5,
Floating LNG regasification facility characterized in that it further comprises a heat exchanger (50) for heating the water discharged from the LNG regasifier (20) to convert to high temperature condensed water. The method of claim 6,
The heat exchanger 50 is used to cool the high temperature cooling water discharged from the air conditioning system on the gas turbine generator 30 or other regasification facilities by using the cooled water discharged from the LENG regasifier 20. Floating LNG regasification plant. The method of claim 3,
Floating LNG regasification facility, characterized in that it further comprises a steam turbine generator 60 for generating electricity by using the steam generated in the exhaust gas heat exchanger (40). The method of claim 8,
The water discharged from the steam turbine generator 60 is mixed with the water discharged from the L regasifier 20 is supplied to the heat exchanger 50, characterized in that the supply to the heat exchanger (50). The method of claim 3,
Floating LNG regasification facility, characterized in that the supply passage 70 for supplying the exhaust gas generated in the exhaust gas heat exchanger 40 to the LNG regasifier 20 is further provided.

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