KR20230072658A - Lng fuel supply method using lng fuel supply system with heat exchange type carburetor - Google Patents

Abstract

The present invention relates to an LNG fuel supply method using an LNG fuel supply system to which a heat exchange type vaporizer is applied. According to the present invention, an ISO tank filled with a liquefied natural gas and the heat exchange type vaporizer are manufactured as one piece, so the same can be installed in a portable form on a generator or an engine in an island area. Additionally, the heat exchange type vaporizer may be driven using a waste heat from a coolant of the already installed generator or engine. Therefore, the liquefied natural gas can be easily converted into a fuel and used in the island area without a separate complicated vaporization facility. The LNG fuel supply method using the LNG fuel supply system to which the heat exchange type vaporizer is applied of the present invention comprises: a charging step; a first supplying step; a recovering step; and a second supplying step.

Description

LNG fuel supply method using an LNG fuel supply system using a heat exchange vaporizer {LNG FUEL SUPPLY METHOD USING LNG FUEL SUPPLY SYSTEM WITH HEAT EXCHANGE TYPE CARBURETOR}

The present invention relates to an LNG fuel supply method using an LNG fuel supply system to which a heat exchange type vaporizer is applied, and more specifically, an ISO tank filled with liquefied natural gas and a heat exchange type vaporizer are integrally manufactured for use in island generators or engines. A heat exchange type that allows easy installation and use of liquefied natural gas in island areas without a separate complex vaporization facility by enabling installation in a portable form and enabling the operation of a heat exchange type vaporizer using the waste heat of cooling water from a pre-installed generator or engine It relates to an LNG fuel supply method using an LNG fuel supply system using a vaporizer.

In general, a natural air type vaporizer is liquefied by heat exchange between liquefied gas and air outside a fin-tube through natural convection by interconnecting a pipe shape with a wing shape using aluminum with excellent thermal conductivity. Means a device that vaporizes gas.

This natural air type vaporizer does not require a separate utility, so maintenance is easy, anyone can easily use it, and in particular, it has the advantage of not incurring additional costs due to re-examination.

However, when the vaporizer is used continuously, the efficiency is reduced due to the freezing phenomenon caused by heat exchange. As it is installed in parallel, it is recommended to operate alternately every 8 hours. There are also problems with installation restrictions.

On the other hand, an ISO tank (in particular, a cylindrical type C ISO tank), which is generally a container for storing liquefied natural gas, is transported by sea through a ship while being accommodated in a standardized container frame in a separate form from the vaporizer, In order to fuel it on land, it is necessary to vaporize natural gas in a liquefied state. To this end, a separate storage space for storing the separately transported ISO tank, a separate vaporizer for vaporizing the liquefied natural gas in the ISO tank, and an installation space for installing it are all required. It is difficult to equip a complex gasification device to fuel and use it in the region.

Therefore, there is a need for a technology for vaporizing and converting a standardized ISO tank into fuel without a separate complicated vaporization device (or vaporization facility).

Korean Patent Registration No. 10-1650073

The present invention is to solve the above-described problems, and the ISO tank filled with liquefied natural gas and the heat exchanger type vaporizer are integrally manufactured so that they can be installed in a portable form in an island generator or engine, and the coolant of the previously installed generator or engine Provides an LNG fuel supply method using an LNG fuel supply system with a heat exchange type vaporizer that enables the operation of a heat exchange type vaporizer using waste heat, so that liquefied natural gas can be easily converted into fuel and used in island areas without a separate complex vaporization facility want to do

An LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer according to an embodiment of the present invention is an ISO tank 110, one side is connected to the ISO tank 110, and the other side is connected to the cooling water supply of an external engine. Connected to the heat exchange type vaporizer 120 for vaporizing the liquefied natural gas supplied from the ISO tank 110 using waste heat of the cooling water supplied from the cooling water supplier, and the ISO tank 110 and the heat exchange type vaporization inside In the LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer including an accommodation container 130 in which an accommodation space in which an apparatus 120 is accommodated is provided, the ISO tank 110 is connected through a connection line. Receiving liquefied natural gas from a liquefied natural gas filling station to charge the ISO tank 110, operating a cooling water pump included in a cooling water supply station to supply cooling water in the direction of the heat exchange type vaporizer 120, Liquefied natural gas is supplied from the ISO tank 110 toward the heat exchange type vaporizer 120, and the liquefied natural gas is subjected to primary heat exchange using waste heat of cooling water circulating through the heat exchange type vaporizer 120 Recovering to the inside of the upper side of the ISO tank 110 and re-introducing the natural gas discharged according to the increase in pressure inside the ISO tank 110 into the heat exchange type vaporizer 120 for secondary heat exchange and then supplying it to the engine steps may be included.

In one embodiment, the heat exchange type vaporizer 120 is connected to a cooling water pump included in the cooling water supply of the external engine, and the liquefied natural gas supplied from the ISO tank 110 and the cooling water supplied through the cooling water pump After exchanging heat with each other, the vaporized natural gas is supplied in the direction of the engine, and the liquefied natural gas supplied from the ISO tank 110 is primarily heat-exchanged by the waste heat of the cooling water and then returned to the ISO tank 110. The natural gas introduced and discharged to the outside by the increase in pressure in the ISO tank 110 may be re-supplied to the heat exchange type vaporizer 120 and then vaporized through secondary heat exchange by waste heat of the cooling water.

In one embodiment, the present invention provides first to third valves 140, 150, 160, the second valve 150 and Primary heat exchange through the fourth valve 170 provided on the connection line branched off from the connection line connecting the third valve 160 and connected to the heat exchange type vaporizer 120 and the heat exchange type vaporizer 120 A fifth valve 180 provided in a connection line for re-introducing the extracted natural gas into the ISO tank 110, and a connection line for re-introducing natural gas in the ISO tank 110 into the heat exchange type vaporizer 120 A sixth valve 190 provided in the heat exchange type vaporizer 120, a seventh valve 200 provided in a connection line for supplying the second heat exchanged and vaporized natural gas to the engine, and the charging of the liquefied natural gas The eighth valve 210 and the first to eighth valves 140, 150, 160, 170, 180, 190, 200, 210 provided in the connection line connecting the upper part of the ISO tank 110 with the It may further include a controller (not shown) for controlling the open/closed state.

In one embodiment, the controller opens the first and eighth valves 140 and 210 before filling the ISO tank 110 with the liquefied natural gas supplied from the liquefied natural gas filling station. After pre-cooling the ISO tank 110 by spraying into the ISO tank 110 in the form of a spray, when the internal temperature of the ISO tank 110 is cooled to a predetermined temperature or less, the seventh valve 210 may be blocked. there is.

In one embodiment, the control unit opens the first to third valves 140, 150, and 160 after the pre-cooling of the ISO tank 110 is completed, so that the liquefied natural gas supplied from the liquefied natural gas filling station It may be filled in the ISO tank 110.

In one embodiment, the control unit opens the first valve 140, the third and fourth valves 160 and 170 so that the liquefied natural gas supplied from the ISO tank 110 is supplied to the heat exchange type vaporizer ( 120), the first heat is exchanged by the waste heat of the cooling water, and then is introduced back into the ISO tank 110, and the pressure in the ISO tank 110 rises as the heat-exchanged liquefied natural gas is reintroduced. By opening the sixth valve 190, natural gas in the ISO tank 110 may be re-introduced into the heat exchange type vaporizer 120.

In one embodiment, the upper and lower sides of the ISO tank 110 may be respectively provided with temperature sensors 220 for measuring temperature changes in the ISO tank 110 .

In one embodiment, the pressure in the ISO tank 110 is measured in real time on the upper side of the ISO tank 110, and the pressure in the ISO tank 110 is automatically opened when it corresponds to a preset pressure or higher. A protection valve 230 may be provided to maintain the set pressure.

According to one aspect of the present invention, an ISO tank filled with liquefied natural gas and a heat exchanger vaporizer are integrally manufactured so that they can be installed in a portable form on an island generator or engine, and using the coolant waste heat of an already installed generator or engine By enabling the operation of the heat exchange type vaporizer, there is an advantage in that liquefied natural gas can be conveniently fueled and used in island areas without a separate and complicated vaporization facility.

In particular, since both the ISO tank and the vaporizer can be accommodated in a standardized container frame, a separate vaporizer and vaporizer installation location are unnecessary.

1 is a diagram showing an LNG fuel supply method using an LNG fuel supply system to which a heat exchange type vaporizer is applied according to an embodiment of the present invention in a series order.
2 is a diagram showing the configuration of an LNG fuel supply system 100 to which a heat exchange type vaporizer is applied according to an embodiment of the present invention.
3 is a view showing a state in which the ISO tank 110 and the heat exchange type vaporizer 120 are accommodated in the accommodation container 130.
4 is a view showing the ISO tank 110 and the heat exchange type vaporizer 120 in more detail.
5 is a view showing the receiving container 130 in more detail.

Hereinafter, a preferred embodiment is presented to aid understanding of the present invention. However, the following examples are only provided to more easily understand the present invention, and the content of the present invention is not limited by the examples.

1 is a view showing an LNG fuel supply method using an LNG fuel supply system to which a heat exchange type vaporizer is applied according to an embodiment of the present invention in a series order, and FIG. 2 is a heat exchange type vaporizer according to an embodiment of the present invention. 3 is a view showing a state in which the ISO tank 110 and the heat exchange type vaporizer 120 are accommodated in the receiving container 130, and FIG. 4 is a view showing the configuration of the LNG fuel supply system 100 to which This is a view showing the tank 110 and the heat exchange type vaporizer 120 in more detail, and FIG. 5 is a view showing the receiving container 130 in more detail.

1 to 5, the LNG fuel supply method using the LNG fuel supply system to which the heat exchange type vaporizer is applied according to the present invention supplies liquefied natural gas from a liquefied natural gas filling station connected to the ISO tank 110 through a connection line. receiving and filling the ISO tank 110 (S101), supplying cooling water in the direction of the heat exchange type vaporizer 120 by operating the cooling water pump included in the cooling water supply point (S102), the ISO tank 110 ) supplies liquefied natural gas in the direction of the heat exchange type vaporizer 120, performs primary heat exchange on the liquefied natural gas using waste heat of the cooling water circulating through the heat exchange type vaporizer 120, and then the ISO tank 110 ) Recovering to the inside of the upper side (S103) and re-introducing the natural gas discharged according to the increase in pressure inside the ISO tank 110 into the heat exchange type vaporizer 120 to perform secondary heat exchange and then supplying it to the engine It may proceed to (S104).

To this end, the LNG fuel supply system 100 to which the heat exchange type vaporizer according to the present invention is applied is largely composed of an ISO tank 110, a heat exchange type vaporizer 120 and a receiving container 130.

The ISO tank 110 is accommodated inside the receiving container 130, receives liquefied natural gas (LNG), and is connected to a liquefied natural gas filling station through a valve provided at one end to receive the liquefied natural gas.

The heat exchange type vaporizer 120 is connected to the ISO tank 110 in the receiving container 130 and vaporizes the liquefied natural gas supplied from the ISO tank 110 using waste heat of the cooling water supplied from the cooling water supply source of the external engine. to supply to the engine direction.

The interior of the accommodation container 130 may be partitioned to accommodate the aforementioned ISO tank 110 and the heat exchange type vaporizer 120, and its size is standardized.

On the other hand, the ISO tank 110, the heat exchange type evaporator 120, the coolant supply source supplied to the heat exchange type evaporator 120, and the engine fueled by natural gas are connected through a plurality of connection lines and a number of pipes. Looking at it in more detail, it is as follows.

Referring to Figure 1, the lower portion of the ISO tank 110 is connected to the liquefied natural gas filling station through a connection line, wherein the connection line is provided with first to third valves 140, 150, 160, respectively.

In addition, the connection line branched from the connection line connecting the second valve 150 and the third valve 160 is connected to the heat exchange type vaporizer 120, and at this time, the fourth valve 170 is provided on the connection line . The liquefied natural gas supplied from the ISO tank 110 is supplied to the heat exchange type vaporizer 120 through the third and fourth valves 160 and 170, and the waste heat of the cooling water supplied to the heat exchange type vaporizer 120 After being primarily heat-exchanged by the heat exchanger 120 and the upper portion of the ISO tank 110 through the fifth valve 180 provided in the connection line connecting the upper portion of the ISO tank 110 again flows into the ISO tank 110.

At this time, the BOG is filled in the ISO tank 110, and the pressure in the ISO tank 110 continues to rise as the natural gas that has been primarily heat-exchanged by the heat exchange type vaporizer 120 continuously flows in. The natural gas, which has undergone the first heat exchange with the BOG gas automatically by the pressure, is pushed back to the outside and re-introduced into the heat exchange type vaporizer 120. At this time, the upper part of the ISO tank 110 and the heat exchange type vaporizer 120 are connected to a connection line for reintroducing the natural gas mixed with BOG into the heat exchange type vaporizer 120. At this time, the connection line has a sixth valve ( 190) is provided.

The natural gas re-introduced into the heat exchange type vaporizer 120 is secondarily heat-exchanged by the waste heat of the cooling water in the heat exchange type vaporizer 120, vaporized, and supplied to the engine through a connection line. At this time, a seventh valve 200 is provided in the connection line.

On the other hand, another connection line may be branched from the connection line connecting the first valve 140 and the second valve 150 described above to be additionally connected to the upper part of the ISO tank 110. At this time, the connection line An eighth valve 210 is provided.

The connection line provided with the eighth valve 210 pre-cools the ISO tank 110 by injecting the liquefied natural gas in the form of a spray before filling the ISO tank 110 with the liquefied natural gas, so that the internal temperature of the ISO tank 110 is below zero. It should be 130 degrees to 140 degrees below zero.

The first to eighth valves 140 to 210 described above are automatically controlled under the control of the control unit to adjust the flow rate of natural gas through each connection line, which is sequentially as follows.

First, all valves 140 to 200 in the LNG fuel supply system 100 to which the heat exchange type vaporizer is applied correspond to a closed state.

The controller first opens the first and eighth valves 140 and 210 to inject liquefied natural gas into the ISO tank 110 in a spray form so that the internal temperature of the ISO tank 110 drops to -130 degrees Celsius to -140 degrees Celsius. do.

At this time, as the temperature sensors 220 capable of measuring the temperature change in the ISO tank 110 are provided on the upper and lower sides of the ISO tank 110, if the temperature in the ISO tank 110 is -130 degrees to -140 degrees Celsius. When falling back, the control unit blocks the eighth valve 210 and opens the second and third valves 150 and 160 to fill the ISO tank 110 with the liquefied natural gas supplied from the liquefied natural gas filling station. .

After filling is completed, the control unit closes the first to third valves 140, 150, and 160, and then opens the third valve 160 and the fourth valve 170 to open the liquefied natural gas in the ISO tank 110. Heat is introduced into the heat exchange type vaporizer 120 and heat exchange is performed primarily by using the waste heat of cooling water passing through the heat exchange type vaporizer 120. At the same time, the control unit opens the fifth valve 180 to reintroduce the primary heat-exchanged natural gas into the upper part of the ISO tank 110 again.

Here, the temperature of the natural gas after the first heat exchange is between about minus 110 degrees and minus 100 degrees. (-110 degrees below zero to -100 degrees below zero) will exist in the upper part of the tank. A temperature change inside the ISO tank 110 may be detected in real time through the temperature sensors 220 provided on the upper and lower sides of the ISO tank 110 .

On the other hand, the internal pressure of the ISO tank 110 is increased by the BOG and the continuously flowing natural gas inside the ISO tank 110, and the control unit opens the sixth valve 190 to increase the pressure in the ISO tank 110 As a result, natural gas along with BOG is automatically introduced into the heat exchange type vaporization device 120, and then heat exchange is performed secondarily using the waste heat of the cooling water. At the same time, the controller opens the seventh valve 200 to supply vaporized natural gas toward the engine. At this time, since the internal pressure of the ISO tank 110 is already high, gaseous natural gas can automatically move to the heat exchange type vaporizer 120 simply by opening the sixth valve 190 in the control unit. . In addition, the temperature of natural gas in a gaseous state after the secondary heat exchange is 30 degrees Celsius to 50 degrees Celsius.

In addition, the control unit detects the pressure inside the ISO tank 110 in real time from the upper side of the ISO tank 110 and then protects the ISO tank 110 and the connection line (piping) when the internal pressure is determined to be higher than the preset design pressure. To do so, the protection valve 230 is opened.

On the other hand, in one embodiment, a connection line connecting the ISO tank 110 and the sixth valve 190 may be additionally branched and connected to the outside, and the natural gaseous state discharged from the ISO tank 110 A ventilation valve 240 for discharging some of the gas to the outside may be additionally provided.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

100: LNG fuel supply system using a heat exchange type vaporizer
110: ISO tank
120: heat exchange vaporizer
130: receiving container
140, 150, 160, 170, 180, 190, 200, 210: first to eighth valves
220: temperature sensor
230: protection valve
240: ventilation valve

Claims (8)

An ISO tank 110, one side of which is connected to the ISO tank 110 and the other side of which is connected to a cooling water supply source of an external engine, liquefies supplied from the ISO tank 110 by using waste heat of the cooling water supplied from the cooling water supply source. A heat exchange type vaporizer including a heat exchange type vaporizer 120 for vaporizing natural gas and a receiving container 130 provided with an accommodation space for accommodating the ISO tank 110 and the heat exchange type vaporizer 120 therein In the LNG fuel supply method using the applied LNG fuel supply system,
Receiving liquefied natural gas from a liquefied natural gas filling station connected to the ISO tank 110 through a connection line and filling the ISO tank 110;
supplying cooling water in the direction of the heat exchange type vaporizer 120 by operating a cooling water pump included in a cooling water supply;
Liquefied natural gas is supplied from the ISO tank 110 toward the heat exchange type vaporizer 120, and the liquefied natural gas is subjected to primary heat exchange using waste heat of cooling water circulating through the heat exchange type vaporizer 120 Recovering to the upper inside of the ISO tank 110; and
Re-introducing the natural gas discharged as the internal pressure of the ISO tank 110 increases into the heat exchange type vaporizer 120 to perform secondary heat exchange and then supplying the natural gas to the engine; LNG fuel supply method using an LNG fuel supply system applied.
According to claim 1,
The heat exchange type vaporization device 120,
It is connected to the cooling water pump included in the cooling water supply of the external engine, heat exchanges between the liquefied natural gas supplied from the ISO tank 110 and the cooling water supplied through the cooling water pump, and then the vaporized natural gas is directed toward the engine. to supply,
The liquefied natural gas supplied from the ISO tank 110 is primarily heat-exchanged by the waste heat of the cooling water, then re-introduced into the ISO tank 110, and discharged to the outside by the pressure rise in the ISO tank 110 LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer, characterized in that natural gas is re-supplied to the heat exchange type vaporizer 120 and then vaporized through second heat exchange by waste heat of the cooling water.
According to claim 2,
First to third valves 140, 150, and 160 provided on a connection line connecting a liquefied natural gas filling station and the ISO tank 110;
a fourth valve 170 branched from a connection line connecting the second valve 150 and the third valve 160 and provided on a connection line connected to the heat exchange type vaporizer 120;
A fifth valve 180 provided in a connection line for re-introducing the natural gas, which has been primarily heat-exchanged through the heat exchange type vaporizer 120, into the ISO tank 110;
A sixth valve 190 provided on a connection line through which natural gas in the ISO tank 110 is re-introduced into the heat exchange type vaporizer 120;
A seventh valve 200 provided in a connection line supplying the second heat exchanged and vaporized natural gas through the heat exchange type vaporizer 120 to the engine;
An eighth valve 210 provided on a connection line connecting the liquefied natural gas filling station and the upper portion of the ISO tank 110; and
A control unit for controlling the opening and closing of the first to eighth valves (140, 150, 160, 170, 180, 190, 200, 210); LNG fuel supply system using a heat exchange type vaporizer, characterized in that it further comprises LNG fuel supply method using.
According to claim 3,
The control unit,
Before filling the liquefied natural gas in the ISO tank 110, the first and eighth valves 140 and 210 are opened to spray the liquefied natural gas supplied from the liquefied natural gas filling station into the ISO tank 110. After pre-cooling the ISO tank 110 by spraying in the form, when the internal temperature of the ISO tank 110 is cooled to a predetermined temperature or less, the seventh valve 210 is blocked, heat exchange type vaporizer LNG fuel supply method using an LNG fuel supply system applied.
According to claim 4,
The control unit,
After the pre-cooling of the ISO tank 110 is completed, the first to third valves 140, 150, and 160 are opened to fill the ISO tank 110 with the liquefied natural gas supplied from the liquefied natural gas filling station. Characterized in that, LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer.
According to claim 3,
The control unit,
By opening the first valve 140, the third and fourth valves 160 and 170, the liquefied natural gas supplied from the ISO tank 110 flows through the heat exchange vaporizer 120, and the waste heat of the cooling water flows. After allowing the heat to be exchanged first by
When the pressure in the ISO tank 110 rises as the heat-exchanged liquefied natural gas is re-introduced, the sixth valve 190 is opened so that the natural gas in the ISO tank 110 is transferred to the heat exchange type vaporizer 120. LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer, characterized in that it is re-introduced into.
According to claim 1,
On the upper and lower sides of the ISO tank 110,
A temperature sensor 220 for measuring a temperature change in the ISO tank 110; LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer, characterized in that each is provided.
According to claim 1,
On the upper side of the ISO tank 110,
A protective valve 230 measures the pressure in the ISO tank 110 in real time and maintains the pressure in the ISO tank 110 at the preset pressure through automatic opening when the pressure is equal to or higher than the preset pressure. Characterized in that, LNG fuel supply method using an LNG fuel supply system using a heat exchange type vaporizer.

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