KR102521169B1 - Offshore HVAC Refrigerant Circulation System using Regas Energy of Liquefied Gas From FSPP - Google Patents

Abstract

The present invention regasifies LNG in a Floating Storage Power Plant and supplies the cooled first refrigerant to the onshore HVAC system, which is required for the production of the second refrigerant to be used for air conditioners in onshore facilities. It is characterized by including a plant refrigerant circulation pipe to be used as a heat source, and energy saving and refrigerant utilization are improved by using the vaporization heat generated when LNG for fuel is regasified in FSPP as a heat source for cooling the refrigerant to be used for land air conditioners, etc. It relates to an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant that can be significantly improved.

Description

Offshore HVAC Refrigerant Circulation System using Regas Energy of Liquefied Gas From FSPP}

The present invention relates to a land HVAC refrigerant circulation system using LNG re-vaporization heat of a floating power plant, and more particularly, the vaporization heat generated during LNG re-vaporization for fuel in FSPP is used as a heat source necessary for cooling the refrigerant to be used in land air conditioners, etc. It relates to an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant, which can significantly improve energy savings and refrigerant utilization by utilizing it.

When using LNG gas as a fuel for a Floating Storage Power Plant (FSPP), LNG is vaporized through a vaporizer.

As something devised from the above point of view, the same thing as "regasification of LNG on board" (hereinafter referred to as 'prior art') of Patent Publication No. 10-2008-0111463 can be mentioned.

Common LNG regasification technology-related devices, including the prior art, mainly use seawater or glycol water as a heat medium used for heat exchange.

At this time, when seawater is used as the refrigerant for LNG regasification, it is discharged into the sea as it is after the heat exchange is completed.

When the seawater whose temperature has been lowered while regasifying LNG is discharged into the sea as it is, there is a problem such as wasting an energy source after heat exchange, and there are also concerns about environmental pollution, such as lowering the temperature of seawater.

Therefore, it is urgent to develop a device and technology for efficiently managing and utilizing the refrigerant after heat exchange.

Patent Publication No. 10-2008-0111463 (published on December 23, 2008)

The present invention was invented to improve the above problems, and by using the heat of vaporization generated during regasification of LNG for fuel in FSPP as a heat source for cooling the refrigerant to be used in land air conditioners, energy saving and utilization of refrigerants are greatly reduced. It is to provide an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant that can improve.

In order to achieve the above object, the present invention provides a plant refrigerant circulation pipe in which a first refrigerant circulates to regasify LNG in a floating power plant (Floating, Storage, Power Plant, hereinafter FSPP); and an air conditioner refrigerant circulation pipe provided in the onshore facility and through which the second refrigerant circulates to produce the second refrigerant to be used for the air conditioner. And a heat exchanger provided in the FSPP or the onshore facility to accommodate partial sections of the plant refrigerant circulation pipe and the air conditioner refrigerant circulation pipe, respectively, and to exchange heat between the first refrigerant and the second refrigerant. It is possible to provide an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant, characterized in that.

Here, the first refrigerant is cooled when the LNG is regasified, and a heat source required for producing the second refrigerant in the heat exchanger is provided to the second refrigerant production facility.

At this time, the LNG storage tank of the FSPP and the gas turbine generator are interconnected and the LNG is transported to the gas turbine generator side, and the LNG supply pipe, and the first refrigerant mounted on the LNG supply pipe and flowing through the plant refrigerant circulation pipe Heat from It characterized in that it further comprises an LNG regasification unit for receiving and regasifying the LNG.

The LNG regasification unit includes at least one LNG regasification pump mounted on the LNG supply pipe and generating pressure for transporting the LNG to the gas turbine generator side, and a discharge side of the LNG regasification pump and the gas turbine generator It is mounted on the LNG supply pipe between, characterized in that it comprises an LNG evaporator through which the plant refrigerant circulation pipe passes.

And, at least one regasification unit installed on the plant refrigerant circulation pipe to generate pressure for the first refrigerant cooled by taking away heat from the LNG as the LNG is regasified and circulated in one direction through the plant refrigerant circulation pipe. It is characterized in that it further comprises a refrigerant pump.

And, the first refrigerant is any one of glycol water, sea water, and cooling water,

The second refrigerant is characterized in that it is an alternative refrigerant for air conditioners including HFCs refrigerants.

In addition, an air conditioner refrigerant supply unit provided in the land facility and connected to the air conditioner refrigerant circulation pipe and supplying a second refrigerant produced by heat exchange between the first refrigerant and the heat exchanger, and a predetermined amount supplied from the air conditioner refrigerant supply unit. It is characterized in that it further comprises a pressure vessel in which the second refrigerant is accommodated, and a transportation means for transporting the plurality of pressure vessels to a place of use.

In addition, the air conditioner refrigerant supply unit, a refrigerant discharge pipe branched from the air conditioner refrigerant circulation pipe at the outlet side of the heat exchanger and through which the second refrigerant is discharged, and mounted on the refrigerant discharge pipe to open and close the flow path of the refrigerant discharge pipe control production volume. A valve and a sensor module mounted on the refrigerant discharge pipe at the inlet side of the production control valve to sense the temperature and pressure of the second refrigerant in real time, wherein the sensor module measures the temperature and pressure of the second refrigerant in real time. When the temperature and pressure reach within the set value range, the production volume control valve is opened and the second refrigerant is injected into the pressure container.

On the other hand, the present invention supplies the cooled first refrigerant to the onshore HVAC system by regasifying LNG in a floating storage power plant, thereby producing a second refrigerant to be used for air conditioners in onshore facilities. It is also possible to provide a land HVAC refrigerant circulation system using LNG regasification heat of a floating power plant, comprising a plant refrigerant circulation pipe to be used as a required heat source.

According to the present invention having the configuration as described above, the following effects can be achieved.

First of all, the present invention utilizes the heat of vaporization generated during regasification of LNG for fuel in a floating power plant (FSPP) as a heat source for cooling the refrigerant used in land air conditioners, etc., thereby significantly improving energy savings and utilization of refrigerants. there is.

In addition, it is possible to save power for refrigerant production in onshore facilities, thereby reducing costs and reducing environmental pollution caused by electricity production.

In addition, heat exchange can be promoted to utilize vaporization heat generated when LNG for fuel is regasified in FSPP as a heat source for cooling refrigerant to be used in land-based air conditioners.

In addition, the refrigerant can be continuously mass-produced and supplied smoothly to the demand side.

In addition, it is possible to supply refrigerant with minimal heat loss even to onshore facilities located far from the FSPP.

1 is a block diagram schematically showing the overall structure of a land HVAC refrigerant circulation system using LNG regasification heat of a floating power plant according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. In this specification, this embodiment is provided to complete the disclosure of the present invention, and to completely inform those skilled in the art of the scope of the invention to which the present invention belongs. And the invention is only defined by the scope of the claims. Thus, in some embodiments, well-known components, well-known operations and well-known techniques have not been described in detail in order to avoid obscuring the interpretation of the present invention.

In addition, like reference numerals designate like elements throughout the specification, and terms used (referred to) in this specification are for describing embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and components and operations referred to as 'comprising (or including)' do not exclude the presence or addition of one or more other components and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

An onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant according to an embodiment of the present invention will be described as an example in which liquefied natural gas (LNG) is applied as a representative liquefied gas. However, it is not limited thereto, and the liquefied gas can be transported by liquefying the gas at a low temperature, and may be a liquefied gas that can be used as a fuel for an engine, such as LNG, LEG (Liquefied Ethane Gas), LPG Liquefied petrochemical gases such as (Liquefied Petroleum Gas), Liquefied Ethylene Gas, and Liquefied Propylene Gas may be applied.

That is, the onshore HVAC refrigerant circulation system using the LNG regasification heat of the floating power plant according to an embodiment of the present invention recovers the wasted cold heat while regasifying the liquefied gas and uses it in the onshore HVAC refrigerant circulation system. to be

HVAC (Heating, Ventilation, Air Conditioning) refers to technology used for the comfort of the internal environment, such as adjusting the internal temperature of indoors, automobiles, nuclear power plants, etc., or ventilating the internal air.

1 is a block diagram schematically showing the overall structure of a land HVAC refrigerant circulation system using LNG regasification heat of a floating power plant according to an embodiment of the present invention. Hereinafter, an embodiment of the present invention will be described with reference to FIG. 1 .

According to one embodiment of the present invention, as shown in FIG. 1, the first refrigerant cooled by regasifying LNG in a Floating Storage Power Plant (FSPP) 40 is supplied to the onshore HVAC system. By doing so, it can be seen that the plant refrigerant circulation pipe 10 is included to be used as a heat source required for producing the second refrigerant to be used for air conditioning in the land facility 50.

First, the plant refrigerant circulation pipe 10 forms a passage through which the first refrigerant for regasifying LNG in the FSPP 40 circulates.

In addition, the air conditioner refrigerant circulation pipe 20 is provided in the onshore facility 50 to form a passage through which the second refrigerant circulates to produce the second refrigerant to be used for the air conditioner.

In addition, the heat exchanger 30 is provided in the FSPP 40 or the onshore facility 50 to accommodate a portion of the plant refrigerant circulation pipe 10 and the air conditioner refrigerant circulation pipe 20, respectively, and the first refrigerant and the second The refrigerants exchange heat with each other.

Of course, the present invention can be applied to the above embodiments, and the following various embodiments are also applicable.

First, it can be seen that the first refrigerant is cooled while regasifying LNG, and the heat exchanger 30 provides a heat source required for production of the second refrigerant to the second refrigerant production facility.

Here, the first refrigerant may be one that regasifies LNG by direct heat exchange with LNG, or one that regasifies LNG by indirect heat exchange by exchanging heat with a heat exchange medium that directly exchanges heat with LNG.

Meanwhile, the present invention may further include an LNG supply pipe 41 and an LNG regasification unit 42 to smoothly regasify LNG.

Here, the LNG supply pipe 41 interconnects the LNG storage tank 40c of the FSPP 40 and the gas turbine generator 40g and forms a flow path through which LNG is transferred to the gas turbine generator 40g.

The LNG regasification unit 42 is mounted on the LNG supply pipe 41 and receives heat from the first refrigerant flowing through the plant refrigerant circulation pipe 10 to regasify the LNG.

For the LNG regasification unit 42, an embodiment including an LNG regasification pump 42pa and 42pb and an LNG evaporator 42e may be applied.

Here, at least one of the LNG regasification pumps 42pa and 42pb is mounted on the LNG supply pipe 41 to generate pressure for transporting the LNG to the gas turbine generator 40g.

At this time, the LNG evaporator 42e is mounted on the LNG supply pipe 41 between the discharge side of the LNG regasification pumps 42pa and 42pb and the gas turbine generator 40g, and the plant refrigerant circulation pipe 10 passes through, LNG takes heat from the first refrigerant and transfers it to the gas turbine generator 40g in a regasified state.

On the other hand, the present invention is mounted on the plant refrigerant circulation pipe 10 to regasify LNG, so that the first refrigerant cooled by taking away heat by LNG generates pressure to circulate in one direction through the plant refrigerant circulation pipe 10 At least one regasification refrigerant pump (11a, 11b) may be further provided.

Here, the first refrigerant may be any one of glycol water, seawater, and cooling water, and the second refrigerant may be an alternative refrigerant for air conditioners including hydrofluorocarbon (HFCs) refrigerants.

On the other hand, the present invention is an air conditioner refrigerant supply unit 51 provided in the land facility 50, connected to the air conditioner refrigerant circulation pipe 20, and supplying the second refrigerant produced by heat exchange with the first refrigerant in the heat exchanger 30 can be further provided.

In addition, the present invention further provides a pressure container (hereinafter not shown) in which the second refrigerant supplied by a certain amount from the air conditioner refrigerant supply unit 51 is accommodated, and a transportation means (hereinafter not shown) for transporting the plurality of pressure containers to a place of use. Of course you can.

Here, the above-described transportation means is any one of a conveyor belt, a land transportation vehicle, a drone, a transportation ship, and a transportation airplane, so long as it is used to transport the pressure container to the place of use.

At this time, the air conditioner refrigerant supply unit 51 is branched from the air conditioner refrigerant circulation pipe 20 at the outlet side of the heat exchanger 30 and is mounted on the refrigerant discharge pipe 51e through which the second refrigerant is discharged, and the refrigerant discharge pipe 51e. A yield control valve 51v that opens and closes the flow path of the refrigerant discharge pipe 51e, and a sensor module mounted on the refrigerant discharge pipe 51e at the inlet side of the yield control valve 51v to sense the temperature and pressure of the second refrigerant in real time. (51s).

Therefore, when the temperature and pressure of the second refrigerant measured in real time by the sensor module 51s reach within the set value range, the production volume control valve 51v is opened and the second refrigerant is injected into the pressure vessel.

Hereinafter, the action and effect of the onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant according to a preferred embodiment of the present invention will be reviewed as follows.

First, the present invention provides a plant refrigerant circulation pipe 10 through which the first refrigerant for regasifying LNG in the FSPP 40 circulates; and an air conditioner refrigerant circulation pipe 20 provided in the land facility 50 and through which the second refrigerant circulates to produce the second refrigerant to be used for the air conditioner. And it is provided in the FSPP (40) or the onshore facility (50) to accommodate a portion of the plant refrigerant circulation pipe (10) and the air conditioner refrigerant circulation pipe (20), respectively, and the first refrigerant and the second refrigerant exchange heat with each other By including a heat exchanger 30, the first refrigerant is cooled during regasification of LNG and provides a heat source required for the production of the second refrigerant in the heat exchanger 30 to the second refrigerant production facility side, Energy saving and refrigerant utilization can be greatly improved by using the heat of vaporization generated when LNG for fuel is regasified in the FSPP (40) as a heat source for cooling the refrigerant to be used in land-based air conditioners.

And, according to the present invention, the LNG storage tank 40c of the FSPP 40 and the gas turbine generator 40g are interconnected and the LNG is transported to the gas turbine generator 40g side LNG supply pipe 41; LNG for fuel in the FSPP (40) By using the heat of vaporization generated during re-vaporization as a heat source for cooling the refrigerant used in ground air conditioners, energy saving and utilization of the refrigerant can be greatly improved.

In addition, the LNG regasification unit 42 according to the present invention is mounted on the LNG supply pipe 41 and generates pressure for transporting LNG to the gas turbine generator 40g. At least one LNG regasification pump (42pa, 42pb) ; An LNG evaporator (42e) mounted on the LNG supply pipe (41) between the gas turbine generator (40g) and the discharge side of the LNG regasification pump (42pa, 42pb), through which the plant refrigerant circulation pipe (10) penetrates; By further comprising , Energy saving and refrigerant utilization can be greatly improved by using the heat of vaporization generated during regasification of LNG for fuel in the FSPP (40) as a heat source necessary for cooling the refrigerant to be used in land-based air conditioners.

And, according to the present invention, as the LNG is regasified by being mounted on the plant refrigerant circulation pipe 10, the first refrigerant cooled by taking away heat by the LNG increases the pressure circulating in the plant refrigerant circulation pipe 10 in one direction. By further comprising at least one regasification refrigerant pump (11a, 11b) that generates, the FSPP (40) uses the heat of vaporization generated when regasifying LNG for fuel as a heat source required for cooling the refrigerant to be used in land air conditioners, etc. heat exchange can be promoted.

In addition, according to the present invention, the air conditioner refrigerant supply unit provided in the land facility 50 and connected to the air conditioner refrigerant circulation pipe 20 and supplying the second refrigerant produced by heat exchange with the first refrigerant in the heat exchanger 30 ( 51); a pressure vessel in which the second refrigerant supplied by a predetermined amount from the air conditioner refrigerant supply unit 51 is accommodated; And transportation means for transporting a plurality of pressure containers to the place of use; by further comprising, the heat of vaporization generated when LNG for fuel is re-vaporized in the FSPP (40) is used as a heat source for cooling the refrigerant to be used in land-based air conditioners, etc. Refrigerants will be continuously mass-produced and supplied smoothly.

In addition, the air conditioner refrigerant supply unit 51 according to the present invention is branched from the air conditioner refrigerant circulation pipe 20 at the outlet side of the heat exchanger 30, and the refrigerant discharge pipe 51e through which the second refrigerant is discharged; a yield control valve 51v mounted on the refrigerant discharge pipe 51e to open and close the passage of the refrigerant discharge pipe 51e; and a sensor module 51s mounted on the refrigerant discharge pipe 51e at the inlet side of the production control valve 51v and sensing the temperature and pressure of the second refrigerant in real time.

When the temperature and pressure of the second refrigerant measured in real time by the sensor module 51s reach within the set value range, the production control valve 51v is opened to inject the second refrigerant into the pressure container, thereby moving away from the FSPP 40. It will be possible to supply refrigerant with minimized heat loss even to land facilities 50 located in distant places.

In addition, in order to circulate the refrigerant used for cooling, the power consumption of the compressor included in the refrigerant cycle is considerable, but it is possible to save power for refrigerant production in onshore facilities, reducing costs and reducing electricity production. environmental pollution can be reduced.

As described above, the present invention utilizes the heat of vaporization generated during regasification of LNG for fuel in FSPP as a heat source necessary for cooling the refrigerant to be used for land air conditioners, etc. A floating power plant that can significantly improve energy savings and utilization of refrigerants It can be seen that the basic technical idea is to provide an onshore HVAC refrigerant circulation system using the regasification heat of LNG.

And, of course, many other modifications and applications are possible to those skilled in the art within the scope of the basic technical idea of the present invention.

10 ... Plant refrigerant circulation pipe
11a, 11b... regasification refrigerant pump
20 ... air conditioner refrigerant circulation pipe
30 ... heat exchanger
40...floating power plant (FSPP)
40c...LNG storage tank
40g... gas turbine generator
41...LNG supply pipe
42 ... LNG regasification unit
42e...LNG evaporator
42pa, 42pb...LNG regasification pump
50...land installations
51 ... air conditioner refrigerant supply
51e ... refrigerant discharge pipe
51s...sensor module
51v...production regulating valve

Claims (9)

A plant refrigerant circulation pipe through which a first refrigerant for regasifying LNG in a floating power plant circulates; and
An air conditioner refrigerant circulation pipe provided in land facilities and through which the second refrigerant circulates to produce a second refrigerant to be used for air conditioners;
A heat exchanger provided in the floating power plant or the onshore facility to accommodate portions of the plant refrigerant circulation pipe and the air conditioner refrigerant circulation pipe, respectively, and to exchange heat between the first refrigerant and the second refrigerant; and
An air conditioner refrigerant supply unit provided in the onshore facility, connected to the air conditioner refrigerant circulation pipe, and supplying a second refrigerant produced by heat exchange between the first refrigerant and the heat exchanger;
The air conditioner refrigerant supply unit,
a refrigerant discharge pipe branched from the air conditioner refrigerant circulation pipe at the outlet side of the heat exchanger and serving as a passage through which the second refrigerant is discharged;
a production control valve mounted on the refrigerant discharge pipe to open and close the passage of the refrigerant discharge pipe; and
A sensor module mounted on the refrigerant discharge pipe at the inlet side of the production control valve to detect the temperature and pressure of the second refrigerant in real time; onshore HVAC using LNG regasification heat of a floating power plant, characterized in that it comprises a. refrigerant circulation system. The method of claim 1,
The first refrigerant,
Onshore HVAC refrigerant using LNG regasification heat of a floating power plant, characterized in that it is cooled while regasifying the LNG and provides a heat source required for the production of the second refrigerant in the heat exchanger to the second refrigerant production facility side circulatory system. The method of claim 1,
An LNG supply pipe interconnecting the LNG storage tank of the floating power plant and the gas turbine generator, the LNG being transported to the gas turbine generator side; and
An LNG regasification unit mounted on the LNG supply pipe to receive heat from the first refrigerant flowing through the plant refrigerant circulation pipe and regasify the LNG; characterized in that it further includes, land using LNG regasification heat of the floating power plant HVAC refrigerant circulation system. The method of claim 3,
The LNG regasification unit,
at least one LNG regasification pump mounted on the LNG supply pipe and generating pressure to transfer the LNG to the gas turbine generator side; and
An LNG evaporator mounted on the LNG supply pipe between the discharge side of the LNG regasification pump and the gas turbine generator, through which the plant refrigerant circulation pipe passes; Onshore HVAC refrigerant circulation system. The method of claim 1,
At least one regasification refrigerant pump mounted on the plant refrigerant circulation pipe to generate pressure for the first refrigerant cooled by regasifying the LNG to circulate in one direction through the plant refrigerant circulation pipe; Characteristically, an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant. The method of claim 1,
The first refrigerant is any one of glycol water, seawater, and cooling water,
The second refrigerant is an onshore HVAC refrigerant circulation system using LNG regasification heat of a floating power plant, characterized in that the alternative refrigerant for air conditioners containing HFCs refrigerant. The method of claim 1,
a pressure container accommodating the second refrigerant supplied by a predetermined amount from the air conditioner refrigerant supply unit; and
A transportation means for transporting a plurality of pressure vessels to a place of use; Characterized in that it further comprises, Land HVAC refrigerant circulation system using LNG regasification heat of a floating power plant. delete delete

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