KR101385574B1 - Leak detection and blocking system for liquid evaporator - Google Patents

Abstract

The present invention is a low temperature liquid for making a liquid or gas at a higher pressure and temperature by pressurizing or heating to supply a low temperature liquefied liquid such as liquefied natural gas (LNG) and liquefied petroleum gas (LPG) to a high pressure gas. Applied to the cargo pressurization device, it can primarily detect the leakage of natural gas, and the leak detection of the liquefied heater to prevent the secondary accident by stopping the supply of heating medium when the natural gas leaks. A blocking system.

Description

Leak detection and blocking system for liquid evaporator

The present invention is a low temperature liquid for making a liquid or gas at a higher pressure and temperature by pressurizing or heating to supply a low temperature liquefied liquid such as liquefied natural gas (LNG) and liquefied petroleum gas (LPG) to a high pressure gas. Applied to the cargo pressurization device, it can primarily detect the leakage of natural gas, and the leak detection of the liquefied heater to prevent the secondary accident by stopping the supply of heating medium when the natural gas leaks. A blocking system.

Generally, low temperature liquefied liquids, such as liquefied natural gas (LNG) and liquefied petroleum gas (LPG), are pressurized or heated to supply high pressure gas to liquid or gas at higher pressure and temperature. A pressurization device is used and consists of a liquefaction storage tank, a high pressure pump and a heater.

The liquefied liquid at about -160 ° C is pressurized through a high pressure pump, and the pressurized liquefied gas is vaporized while passing through a heater to supply a high temperature and high pressure vaporized gas to an engine. In the heater, the heating medium exchanges heat with low temperature liquefaction and is circulated through the heating medium regenerator.

However, the conventional heater has a problem that gas may leak inside the heater, and when the gas leaks, a situation in which the gas is mixed with the heating medium occurs.

For example, when natural gas leaks and mixes with steam, which is a heating medium, natural gas mixed with steam may enter the boiler through steam condensate, which leads to a large accident such as a fire or an explosion.

In particular, in the case of ships, there is a problem in that a heating medium regeneration source is usually located in the engine room of the ship, thus additionally increasing the risk.

Republic of Korea Patent No.0808777 (2008.2.22, Exhaust gas treatment system of liquefied natural gas regasification facility) Republic of Korea Patent No. 0681545 (Aug. 2007, Carburetor of Cargo System for LNG Carrier) Republic of Korea Patent Publication No. 2012-0019991 (2012.3.7, LNG natural gas vaporization system and vaporization method)

The present invention has been made in order to solve the above problems, it is possible to primarily detect the leakage of natural gas, the liquid to stop the supply of the heating medium in the event of leakage of natural gas to prevent secondary accidents Its purpose is to provide a leak detection and blocking system for cargo heaters.

It is also an object of the present invention to provide a leak detection and blocking system of a liquefied heater to temporarily store and treat leaking gas and heating medium.

The present invention, the high pressure pump 10 for raising the pressure by receiving a low temperature, low pressure liquefaction; A heater 20 which receives a high pressure liquid from the high pressure pump 10 and increases a temperature; A heating medium inlet line 30 connected to the heating medium inlet of the heater 20 to allow the heating medium to exchange heat with the liquefaction into the heater 20; A heating medium inlet shutoff valve (35) installed in the heating medium inlet line (30); A second sensing unit 25 having at least one of a pressure sensor, a temperature sensor, and a gas sensor installed in the heater 20; And a control unit for controlling the heating medium inlet shutoff valve 35 to be blocked according to the signal detected by the second sensing unit 25. The leak detection and blocking system of the liquefied heater is provided. .

In the present invention, the heating medium discharge line 40 is connected to the heating medium outlet of the heater 20, the heating medium is discharged from the heater 20; A heating medium outlet shutoff valve (45) installed in the heating medium discharge line (40); A leakage gas accumulation tank 60 installed in the heating medium discharge line 40 to store the leaked gas and the heating medium; And a first sensing unit 65 in which at least one of a pressure sensor, a temperature sensor, a gas sensor, and a water level sensor is installed in the leaking gas accumulation tank 60. The control unit may further include the first sensing unit. It provides a leakage detection and blocking system of the liquefied heater, characterized in that the control to block the heating medium inlet shut-off valve 35 in accordance with the signal detected from the section (65).

In the present invention, the heating medium outlet blocking valve 45 is provided on the outlet side of the leak gas accumulation tank 60 provides a leak detection and blocking system of the liquefied heater.

In the present invention, the heating medium is steam, is installed in the heating medium discharge line 40, disposed on the inlet side of the leak gas accumulation tank 60, the condensed water generated in the heater 20 is stored Being steam trap 80; And a third sensing unit 70 installed at the heating medium discharge line 40 and installed at an inlet side of the steam trap 80 to detect a level of the condensate. In addition, the controller provides a leakage detection and blocking system of a liquefied heater, characterized in that the control to block the heating medium inlet shut-off valve 35 in accordance with the signal detected from the third sensing unit (70).

According to the leak detection and blocking system of the liquefied heater of the present invention, there are the following effects.

The second sensing unit 25 may primarily detect that natural gas leaks from the evaporation tube 21, and the control unit may control the heating medium inlet shutoff valve according to a signal detected from the second sensing unit 25. 35), it is possible to prevent the secondary accident by stopping the supply of the heating medium in case of leakage of natural gas.

In addition, the natural gas leak can be more effectively monitored by the first sensing unit 65, and the leaked gas storage tank 60 is installed in the heating medium discharge line 40 to prevent leakage of the natural gas and the heating medium. Can be stored temporarily for processing.

Meanwhile, when the natural gas leaks, the water level of the steam trap 80 is reduced, so that the water level detector installed in the heating medium discharge line 40 may detect the leakage of natural gas, and the second detection installed in the heater 20. The unit 25 primarily detects the leakage of natural gas, and the first detection unit 65 also detects the leakage gas accumulation tank 60 to shut off the heating medium inlet shutoff valve 35 by the controller. The supply of can be stopped.

Furthermore, the steam mixed with the already leaked natural gas is stored in the leak gas accumulation tank 60, thereby preventing the secondary risk.

1 is a schematic diagram showing a leak detection and blocking system of a liquefied heater according to a first embodiment of the present invention.
2 and 3 are schematic views showing the operation of the controller in FIG.
4 is a schematic diagram showing a leak detection and blocking system of a liquefied heater according to a second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

Leak detection and blocking system of the liquefied heater described in the embodiment of the present invention is further pressurized or heated to supply a low temperature liquefied liquid such as liquefied natural gas (LNG), liquefied petroleum gas (LPG) It can be applied to a low-temperature liquefied pressurization device for making a liquid or gas of a high pressure and temperature, in particular in the following examples will be described as an LNG heater as an example, but is not limited thereto.

First, a leak detection and blocking system of a liquefied heater according to a first embodiment of the present invention is shown in FIG.

According to Figure 1, the leak detection and blocking system of the liquefied heater according to the first embodiment is the high pressure pump 10, the heater 20, the heating medium inlet line 30 and the heating medium inlet shutoff valve 35 and heating And a medium discharge line 40, a heating medium outlet shutoff valve 45, a second sensing unit 25, a control unit (not shown), a leaking gas accumulation tank 60, and a first sensing unit 65.

The low temperature and low pressure LNG stored in the LNG storage tank (not shown) is supplied to the high pressure pump 10 to increase the pressure, and the low temperature LNG with the increased pressure flows into the heater 20 through the LNG inflow line 11. do. The LNG inlet line 11 is provided with an LNG inlet blocking valve 12 so as to block the inflow of LNG as necessary.

The low temperature LNG introduced into the heater 20 exchanges heat with the high temperature heating medium supplied into the heater 20 while flowing the evaporation tube 21 in the heater 20 to generate vaporized gas. The generated gas is supplied to the high pressure gas.

A heating medium inlet line 30 for introducing a heating medium into the heater 20 is connected to the heating medium inlet of the heater 20.

The heating medium inlet valve 30 is provided in the heating medium inlet line 30 so as to block the inflow of the heating medium, if necessary, and a non-return valve 36 for preventing the backflow of the heating medium. .

The heating medium discharge line 40 for discharging the heating medium, which has undergone heat exchange with the liquefaction, from the heater 20 is connected to the heating medium outlet of the heater 20.

The heating medium outlet line 40 is provided with a heating medium outlet shutoff valve 45 for blocking the discharge of the heating medium, if necessary.

It is configured as described above, the high temperature heating medium is introduced into the heater 20 through the heating medium inlet line 30, and after the heating medium and the liquefaction is heat exchanged, the heating medium through the heating medium discharge line 40 It is discharged from the heater 20.

On the other hand, the heater 20 is preferably provided with a second sensing unit 25, the second sensing unit 25 may be at least one of a pressure sensor, a temperature sensor, a gas sensor.

As shown in FIG. 2, in the present embodiment, a pressure sensor, a temperature sensor, and a gas sensor are all installed in the heater 20, and natural gas leaks from the evaporation tube 21 by the second detection unit 25. Can be detected primarily.

In this way, the control unit blocks the heating medium inlet shutoff valve 35 according to the signal detected by the second sensing unit 25, so that the supply of the heating medium is stopped when the natural gas leaks, thereby preventing the secondary accident.

On the other hand, according to the embodiment, the leakage gas accumulation tank 60 and the first sensing unit 65 may be installed in the heating medium discharge line 40.

As shown in FIG. 1, the leak gas accumulation tank 60 is installed in the heating medium discharge line 40 to store the leaked natural gas and the heating medium. At this time, the heating medium outlet blocking valve 45 is preferably disposed on the outlet side of the leak gas accumulation tank (60).

The leak detection gas storage tank 60 is provided with a first detection unit 65, the first detection unit 65 may be at least one of a pressure sensor, a temperature sensor, a gas sensor, a water level sensor.

In this embodiment, all of the pressure sensor, the temperature sensor, the gas sensor, and the water level sensor are provided in the leak gas accumulation tank 60.

In this way, it is possible to more effectively monitor the natural gas leakage by the first detection unit 65, by installing the leakage gas accumulation tank 60 in the heating medium discharge line 40 to leak the natural gas and heating medium Can be stored temporarily for processing.

3, as shown in FIG. 3, when natural gas leaks through the evaporation tube 21 inside the heater 20, the leakage gas accumulation tank 60 separately installed outside the heater 20 is affected. Due to the gas leaking, the first detecting unit 65 installed in the leaking gas accumulation tank 60 detects this, and the control unit cuts off the heating medium inlet according to the signal detected from the first detecting unit 65. By shutting off the valve 35, the supply of the heat medium is stopped when the natural gas leaks.

The heater 20 is connected with a first emergency discharge valve 91 for emergency discharge of the heating medium and a first discharge line 90 which is provided with a first pressure safety valve 92 for pressure control. In the leakage gas storage tank 60, a second emergency discharge valve 96 for emergency discharge of the heating medium and a second pressure relief valve 97 for pressure control are provided, respectively; Is connected, the first discharge line 90 and the second discharge line 95 is combined together to form a third discharge line (98).

Next, the leak detection and blocking system of the liquefied heater according to the second embodiment of the present invention is shown in FIG.

According to Figure 4, the leak detection and blocking system of the liquefied heater according to the second embodiment is applied when the heating medium is steam, the high pressure pump 10, the heater 20 and the heating medium inlet line 30 and Heating medium inlet shutoff valve 35, heating medium outlet line 40, heating medium outlet shutoff valve 45, second sensing unit 25, control unit (not shown), leakage gas accumulation tank 60, and first The detector 65 includes a steam trap 80 and a third detector 70.

In the second embodiment, the same components as those of the first embodiment are denoted by the same reference numerals, and detailed descriptions of the same components as those of the first embodiment are omitted, so please refer to the first embodiment.

Steam trap 80 is installed in the heating medium discharge line 40, is disposed on the inlet side of the leak gas accumulation tank 60, the condensate generated in the heater 20 is stored.

That is, steam, which is a heating medium, is made of condensed water by heat exchange with low temperature LNG, and a steam trap 80 collecting the condensed water is installed in the heating medium discharge line 40.

In addition, a third sensing unit 70 is installed in the heating medium discharge line 40. In the present embodiment, the third sensing unit 70 is a water level sensor, and is installed at the inlet side of the steam trap 80 to provide condensate. The water level can be detected.

That is, when the natural gas leaks, the water level of the steam trap 80 is reduced, so that the leak of the natural gas can be detected by the water level detector installed in the heating medium discharge line 40.

The control unit blocks the heating medium inlet shutoff valve 35 according to the signal detected from the third sensing unit 70.

In addition, the first detection unit 65 detects leakage of natural gas primarily by the second detection unit 25 installed in the heater 20, and the first detection unit 65 also detects the leakage gas accumulation tank 60 by the controller. The supply of steam can be stopped by blocking the heating medium inlet shutoff valve 35.

Steam already mixed with the leaked natural gas is stored in the leaking gas accumulation tank 60, thereby preventing the secondary risk.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

10: high pressure pump 20: heater
21: evaporation tube 25: second detection unit
30: heating medium inlet line 35: heating medium inlet shutoff valve
40: heating medium discharge line 45: heating medium outlet shutoff valve
60: leaking gas accumulation tank 65: the first detection unit
70: third detection unit 80: steam trap

Claims (4)

High pressure pump 10 for raising the pressure by receiving a low temperature, low pressure liquefied;
A heater 20 which receives a high pressure liquid from the high pressure pump 10 and increases a temperature;
A heating medium inlet line 30 connected to the heating medium inlet of the heater 20 to allow the heating medium to exchange heat with the liquefaction into the heater 20;
A heating medium inlet shutoff valve (35) installed in the heating medium inlet line (30);
A heating medium discharge line 40 connected to the heating medium outlet of the heater 20 to discharge the heating medium from the heater 20;
A heating medium outlet shutoff valve (45) installed in the heating medium discharge line (40);
A leakage gas accumulation tank 60 installed in the heating medium discharge line 40 and temporarily storing the leaked gas and the heating medium; And
A first detector (65) installed at least one of a pressure sensor, a temperature sensor, a gas sensor, and a water level sensor in the leak gas accumulation tank 60 to detect a gas leak;
A second discharge line 96 connected to the leak gas accumulation tank 60 and provided with a second pressure safety valve 97 for pressure control; And
A control unit controlling the heating medium inlet shutoff valve 35 to be blocked according to the signal detected by the first detection unit 65; Leak detection and prevention system of the liquefied product, characterized in that the heater comprises a. The method of claim 1,
The leak detection and blocking system of the liquefied heater
A second sensing unit 25 having at least one of a pressure sensor, a temperature sensor, and a gas sensor installed in the heater 20; Further comprising:
The control unit is a leakage detection and blocking system of the liquefied heater, characterized in that the control to block the heating medium inlet shut-off valve 35 in accordance with the signal detected from the second detection unit (25) . 3. The method of claim 2,
The heating medium outlet shutoff valve (45) is leak detection and blocking system of the liquefied heater, characterized in that disposed on the outlet side of the leakage gas accumulation tank (60). The method according to claim 2 or 3,
The heating medium is steam,
A steam trap (80) installed in the heating medium discharge line (40) and disposed at an inlet side of the leaking gas accumulation tank (60) to store condensed water generated in the heater (20 ); And
A third sensing unit 70 installed at the heating medium discharge line 40 and installed at an inlet side of the steam trap 80 and including a water level sensor capable of sensing the level of the condensate; ,
The control unit is a leakage detection and blocking system of a liquefied heater , characterized in that the control to block the heating medium inlet shut-off valve 35 in accordance with the signal detected from the third detection unit (70).

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