KR102201246B1 - System for inerting and aerating storage tank, and method thereof - Google Patents

Abstract

The present invention relates to a system and method for inactivation and ventilation of a storage tank, and more specifically, to prevent the effects of freezing when operating at a low temperature by using nitrogen gas and air respectively for inactivation and ventilation of the storage tank. It is possible to achieve a piston effect during replacement by making the nitrogen gas and air have a density difference by heating or cooling, but thermal equilibrium inside the storage tank by gradually heating or cooling nitrogen gas or air. It is possible to prevent the decrease in density difference due to this, and thereby maximize the piston effect.

Description

BACKGROUND OF THE INVENTION Field of the Invention: System for inerting and aerating storage tank, and method thereof

The present invention relates to a storage tank inert and venting system and method, and more specifically, to a storage tank inert and venting system and method configured to facilitate the inert and venting process of the storage tank. .

In general, in LNG FPSO (LNG Floating, Production, Storage and Offloading), a storage tank for storing liquefied natural gas (hereinafter referred to as "LNG") or condensate is installed.

Maintenance and repair of the storage tank is performed in a state where the storage tank is completely emptied.To this end, the storage tank is emptied, the residue is evaporated through a warm-up process, and then inerting or purging. ) After carrying out the process, make sure that the storage tank has an environment suitable for maintenance and repair through an aeration process.

In addition, after completing the maintenance and repair of the storage tank, before storing the stored material in the storage tank, the stored material is stored after minimizing the amount of air remaining in the storage tank through an inert process again.

Here, the principle of performing the aeration process after the inert process is that when air is injected into the storage tank filled with inert gas, a piston effect occurs due to the difference in density between the inert gas and the air. By pushing the gas out of the storage tank, the air inside the storage tank is replaced with the inert gas.

In the case of oil FPSO, when the inert gas generated through an inert gas generator is supplied, an inert gas containing carbon dioxide is used.In this way, when an inert gas containing carbon dioxide is used in the storage tank of LNG FPSO However, due to the characteristics of LNG FPSO operated at very low temperatures, freezing of carbon dioxide may occur, which may adversely affect operation.

Therefore, in the case of LNG FPSO, in order to eliminate the freezing of carbon dioxide, nitrogen gas is used in the inert process instead of carbon dioxide. As a prior art for this, "using nitrogen gas" in Korean Patent Laid-Open Patent No. 10-2010-0112708 There is a "replacement method of liquefied gas storage tank".

This prior art is a method of replacing the liquefied gas storage tank for replacing the gas inside the liquefied gas storage tank by using an inert gas for maintenance of the liquefied gas storage tank containing the cryogenic liquefied gas. A first deactivation step of supplying the liquefied gas storage tank to remove the remaining natural gas; A venting step of supplying air into the liquefied gas storage tank so that an operator can access the inside of the liquefied gas storage tank; And a second deactivation step of removing oxygen by supplying nitrogen gas gas to the inside of the liquefied gas storage tank after the operator approaches the inside of the liquefied gas storage tank to complete the maintenance work.

However, conventionally, when nitrogen gas is used in the inert process, the molecular weight of the nitrogen gas is 28.016, and the difference between the molecular weight of the air is about 29, so that a smooth ventilation process by the piston effect cannot be expected.

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The present invention is to solve the conventional problems as described above, when replacing by making the nitrogen gas and air used for inerting and aerating a storage tank have a density difference by heating or cooling The piston effect is exerted, but by gradually heating or cooling nitrogen gas or air to prevent the decrease in density difference due to thermal equilibrium inside the storage tank, and by maximizing the piston effect, inactivation and ventilation of the storage tank are prevented. The purpose is to make it work smoothly.

According to an aspect of the present invention for achieving the above object, there is provided a system for inactivating and venting a storage tank, comprising: a nitrogen gas supply unit for supplying nitrogen gas to the storage tank; An air supply unit supplying air to the storage tank; An opening and closing unit for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit and air supplied from the air supply unit, respectively; A cooling unit for cooling nitrogen gas supplied to the storage tank from the nitrogen gas supply unit; And a control unit for controlling the cooling unit so as to gradually cool the nitrogen gas.

According to another aspect of the present invention, there is provided a system for inactivating and venting a storage tank, comprising: a nitrogen gas supply unit for supplying nitrogen gas to the storage tank; An air supply unit supplying air to the storage tank; An opening and closing unit for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit and air supplied from the air supply unit, respectively; A heating unit for heating air to be supplied to the storage tank from the air supply unit; And there is provided a storage tank inert and ventilation system including a control unit for controlling the heating unit to gradually heat the air.

In addition, a cooling unit for cooling the nitrogen gas supplied to the storage tank from the nitrogen gas supply unit may be further included, and the control unit may control the cooling unit to gradually cool the nitrogen gas.

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According to another aspect of the present invention, there is provided a system for inert and ventilating a storage tank, comprising: a nitrogen gas supply unit for supplying nitrogen gas to the storage tank; An air supply unit supplying air to the storage tank; An opening and closing unit for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit and air supplied from the air supply unit, respectively; A heating unit for heating nitrogen gas to be supplied to the storage tank from the nitrogen gas supply unit; And there is provided a storage tank inert and ventilation system including a control unit for controlling the heating unit to gradually heat the nitrogen gas.

According to another aspect of the present invention, there is provided a system for inert and ventilating a storage tank, comprising: a nitrogen gas supply unit for supplying nitrogen gas to the storage tank; An air supply unit supplying air to the storage tank; An opening and closing unit for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit and air supplied from the air supply unit, respectively; A cooling unit that cools air supplied to the storage tank from the air supply unit; And a control unit for controlling the cooling unit so as to gradually cool the air.

Further, a heating unit for heating nitrogen gas to be supplied to the storage tank from the nitrogen gas supply unit may be further included, and the control unit may control the heating unit to gradually heat the nitrogen gas.

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According to another aspect of the present invention, there is provided a method for inertizing and venting a storage tank, comprising: an inert step of gradually cooling nitrogen gas and supplying it to the storage tank to fill the storage tank with nitrogen gas; And an aeration step of supplying air to the storage tank to replace nitrogen gas with air in the storage tank.

According to another aspect of the present invention, there is provided a method of inactivating and venting a storage tank, comprising: an inert step of supplying nitrogen gas to the storage tank so that nitrogen gas is filled in the storage tank; And an aeration step of replacing nitrogen gas with air in the storage tank by gradually heating and supplying air to the storage tank.

In addition, in the inert step, the nitrogen gas may be gradually cooled and supplied to the storage tank.

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According to another aspect of the present invention, there is provided a method of inactivating and venting a storage tank, comprising: an inert step of gradually heating nitrogen gas and supplying it to the storage tank to fill the storage tank with nitrogen gas; And an aeration step of supplying air to the storage tank to replace nitrogen gas with air in the storage tank.

According to another aspect of the present invention, there is provided a method of inactivating and venting a storage tank, comprising: an inert step of supplying nitrogen gas to the storage tank so that nitrogen gas is filled in the storage tank; And a venting step of replacing nitrogen gas with air in the storage tank by gradually cooling and supplying air to the storage tank.

In addition, in the inert step, the nitrogen gas may be gradually heated and supplied to the storage tank.

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According to another aspect of the present invention, in a method of performing inertness and ventilation of a storage tank, nitrogen gas for an inert process is supplied to the storage tank, and air for aeration process to the storage tank after the inert process is completed. However, there is provided a method of inert and ventilating a storage tank in which nitrogen gas and air have different densities by supplying the nitrogen gas and air at different supply temperatures.

According to the present invention, nitrogen gas and air are respectively used for inactivation and ventilation of the storage tank, thereby preventing the effect of freezing when operating at a low temperature, and the density difference between nitrogen gas and air due to heating or cooling. The piston effect can be exerted upon replacement by having a, and the reduction in density difference due to thermal equilibrium inside the storage tank can be prevented by gradually heating or cooling nitrogen gas or air, thereby maximizing the piston effect. Therefore, inactivation and ventilation of the storage tank are made smoothly.

1 is a block diagram showing an inert and ventilating system of a storage tank according to a first embodiment of the present invention.
2 is a block diagram showing a system for inert and ventilating a storage tank according to a second embodiment of the present invention.
3 is a block diagram showing an inert and ventilating system of a storage tank according to a third embodiment of the present invention.
4 is a block diagram showing an inert and ventilation system of a storage tank according to a fourth embodiment of the present invention.
5 is a block diagram showing an inert and ventilation system of a storage tank according to a fifth embodiment of the present invention.
6 is a block diagram showing an inert and ventilation system of a storage tank according to a sixth embodiment of the present invention.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following examples may be modified in various different forms, and the scope of the present invention is not limited to the following examples.

1 is a block diagram showing an inert and ventilating system of a storage tank according to a first embodiment of the present invention.

As shown in FIG. 1, the storage tank inert and ventilation system 100 according to the first embodiment of the present invention includes a nitrogen gas supply unit 110 for supplying nitrogen gas to the storage tank 10; An air supply unit 120 supplying air to the storage tank 10; An opening/closing unit 130 for opening and closing supply of nitrogen gas and air, respectively; A cooling unit 140 for cooling nitrogen gas; And a control unit 150 for controlling the cooling unit 140.

The storage tank 10 may be, for example, a tank for storing LNG (Liquefied Natural Gas) or condensate as a storage material, and a tank installed for storage of LNG in an LNG carrier or an LNG Regasification Vessel (RV) In addition, it may be a tank that is installed for storage of LNG in floating offshore structures such as LNG FPSO (LNG Floating, Production, Storage and Offloading) or LNG FSRU (LNG Floating Storage and Regasification Unit). It may be a tank used for storage of various stocks including.

The nitrogen gas supply unit 110 may include a generator generating nitrogen gas or a container in which nitrogen gas is compressed and stored, and nitrogen gas to the storage tank 10 through the supply line 160 by the pressure of the generated or stored nitrogen gas. Is supplied, or nitrogen gas may be supplied to the storage tank 10 by using a pump.

The air supply unit 120 may use a compressor or a blower to supply air to the storage tank 10.

The opening/closing unit 130 opens and closes the supply of nitrogen gas supplied from the nitrogen gas supply unit 110 and the air supplied from the air supply unit 120, respectively. To this end, as in the present embodiment, the cooling unit ( It may include valves 131 and 132 respectively installed at the front and rear ends of 140, and a valve 133 installed at the rear end of the air supply unit 120, and a valve 134 installed at the discharge line 170 is further provided. Can include. These valves 131, 132, 133, and 134 may be configured as control valves to be controlled by the control unit 150.

The cooling unit 140 cools the nitrogen gas supplied from the nitrogen gas supply unit 110 to the storage tank 10, and for this purpose, for example, nitrogen is cooled by heat exchange with a refrigerant that is circulated and supplied by cooling by a cooling cycle. The gas can be cooled.

The control unit 150 may control the cooling unit 140 to gradually cool the nitrogen gas. Therefore, the cooling unit 140 gradually cools the nitrogen gas under the control of the control unit 150, so that even if the inert process and the aeration process for the storage tank 10 take a long time, for example, 10 hours or more, the storage tank ( 10) The thermal equilibrium between the low temperature nitrogen gas and the room temperature air is suppressed, thereby maximizing the piston effect due to the density difference between the nitrogen gas and air.

The control unit 150 may control the cooling unit 140 to gradually cool the nitrogen gas at a set time interval, and control the cooling unit 140 to gradually cool the nitrogen gas in proportion to time. In this case, the controller 150 may be provided with a timer 151 for counting a set time or the like. The control unit 150 may gradually increase the output of the cooling unit 140 at every set time, and unlike this, the control unit 150 receives a signal from the temperature sensor 152 that measures the temperature of the nitrogen gas cooled by the cooling unit 140. In response, the cooling unit 140 may be controlled based on this. The cooling temperature and cooling rate of nitrogen gas under the control of the control unit 150 may be determined in consideration of the size and structure of the storage tank 10, the movement path of the nitrogen gas and air in the storage tank 10, and the physical properties of the storage. For example, it may be determined experimentally or by simulation, or by various other calculation methods to be suitable for exerting the piston effect.

The control unit 150 controls the opening/closing valves 131, 132, 133, and 134 of the opening/closing unit 130, respectively, to perform a predetermined inert process and a ventilation process, so that the nitrogen gas from the nitrogen gas supply unit 110 and the air from the air supply unit 120 May be sequentially supplied to the storage tank 10, and further, operations of the nitrogen gas supply unit 110 and the air supply unit 120 may be controlled.

The storage tank 10 includes a supply line 160 for supplying nitrogen gas supplied from the nitrogen gas supply unit 110 and air supplied from the air supply unit 120, and a discharge line 170 for discharging nitrogen gas and air inside. ) Are connected respectively. At this time, as in the present embodiment, nitrogen gas supplied for inertness has a lower temperature than air, so in consideration of the high density, in the aeration process performed after the inert process, nitrogen gas having a relatively high density is relatively dense. It is advantageous to allow nitrogen gas and air to move from the top to the bottom in the storage tank 10 so as to be smoothly replaced with low air.

2 is a block diagram showing a system for inert and ventilating a storage tank according to a second embodiment of the present invention.

As shown in FIG. 2, the storage tank inert and ventilation system 200 according to the second embodiment of the present invention includes a nitrogen gas supply unit 210 for supplying nitrogen gas to the storage tank 10, and a storage tank ( 10) an air supply unit 220 for supplying air, an opening/closing unit 230 for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit 210 and air supplied from the air supply unit 220, respectively, and an air supply unit ( It may include a heating unit 240 for heating air to be supplied to the storage tank 10 from 220, and a controller 250 for controlling the heating unit 240 to gradually heat the air.

In this embodiment, a description of the same configuration as that of the storage tank inactivation and ventilation system 100 according to the first embodiment of the present invention will be omitted.

The opening/closing unit 230 includes a valve 231 installed at the rear end of the nitrogen gas supply unit 210 in the supply line 260 and valves 232 and 233 respectively installed at the front and rear ends of the heating unit 240 as in this embodiment. It may include, and may further include a valve 234 installed in the discharge line 270. These valves 231, 232, 233, and 234 may be formed as control valves to be controlled by the control unit 250.

The heating unit 240 may include a heating member such as a heating element for heating the air supplied from the air supply unit 220, or a heat exchanger that heats air by heat exchange with a heat medium supplied by circulation.

As in the previous embodiment, the controller 250 may further include a timer 251 and a temperature sensor 252 for gradual heating of air.

In addition, the heating temperature and heating rate of the air under the control of the control unit 250 are comprehensively determined by the size and structure of the storage tank 10, the movement path of nitrogen gas and air in the storage tank 10, and the physical properties of the storage. In consideration of this, it may be determined experimentally or by simulation or other various calculation methods to be suitable for exerting the piston effect.

The supply line 260 and the discharge line 270 are relocated to facilitate ventilation in consideration of the fact that the air supplied afterwards to the storage tank 10 has a high temperature and a lower density than the previously supplied nitrogen gas. As in the embodiment, by connecting to the upper and lower portions of the storage tank 10, respectively, nitrogen gas and air may be moved from the upper side to the lower side within the storage tank 10.

3 is a block diagram showing an inert and ventilating system of a storage tank according to a third embodiment of the present invention.

As shown in Figure 3, the storage tank inert and ventilation system 300 according to the third embodiment of the present invention, as in the storage tank inert and ventilation system 200 according to the second embodiment of the present invention, nitrogen Including the gas supply unit 310, the air supply unit 320, the opening and closing unit 330, the heating unit 340 and the control unit 350, but additionally nitrogen gas to be supplied to the storage tank 10 from the nitrogen gas supply unit 310 It may further include a cooling unit 380 to cool. Accordingly, it is possible to easily increase the temperature difference between nitrogen gas and air supplied to the storage tank 10 to maximize the piston effect. In this embodiment, the storage tank according to the first and second embodiments of the present invention Description of the same configuration as the inert and ventilation systems 100 and 200 will be omitted.

As in the present embodiment, the opening and closing part 330 includes valves 331 and 332 respectively installed at the front and rear ends of the cooling unit 380 in the supply line 360 and valves 333 and 334 respectively installed at the front and rear ends of the heating unit 340. ), and may further include a valve 335 installed in the discharge line 370. These valves 331, 332, 333, 334, and 335 may be formed as control valves to be controlled by the control unit 350.

The control unit 350 controls the cooling unit 380 for gradual cooling of nitrogen gas and the heating unit 340 for gradual heating of air. To this end, the timer 351 and the cooling unit 380 ) May include temperature sensors 352 and 353 for measuring the temperatures of the nitrogen gas cooled by and the air heated by the heating unit 340, respectively.

The supply line 360 and the discharge line 370 are relocated to facilitate ventilation in consideration of the fact that the air supplied afterwards to the storage tank 10 has a higher temperature than the previously supplied nitrogen gas and has a lower density. As in the examples, by connecting to the upper and lower portions of the storage tank 10, respectively, nitrogen gas and air may move from the upper side to the lower side in the storage tank 10.

4 is a block diagram showing an inert and ventilation system of a storage tank according to a fourth embodiment of the present invention.

As shown in Figure 4, the storage tank inert and venting system 400 according to the fourth embodiment of the present invention includes a nitrogen gas supply unit 410 for supplying nitrogen gas to the storage tank 10, and the storage tank ( 10) an air supply unit 420 for supplying air, an opening/closing unit 430 for opening/closing the supply of nitrogen gas supplied from the nitrogen gas supply unit 410 and air supplied from the air supply unit 420, and a nitrogen gas supply unit A heating unit 440 for heating nitrogen gas to be supplied to the storage tank 10 from 410, and a control unit 450 for controlling the heating unit 440 to gradually heat the nitrogen gas may be included. .

The storage tank inert and ventilation system 400 according to the fourth embodiment of the present invention is a storage tank inactivation and ventilation system according to the second embodiment of the present invention in which air is gradually heated and supplied to the storage tank 10. Unlike 200, the heating target differs in that nitrogen gas is gradually heated by the heating unit 440 controlled by the control unit 450 and supplied to the storage tank 10, but nitrogen gas and air Since the inert and ventilation system 200 of the storage tank according to the second embodiment of the present invention are the same in that they have a density difference, a duplicate description will be omitted.

The opening/closing unit 430 includes valves 431 and 432 respectively installed at the front and rear ends of the heating unit 440 in the supply line 460 as in this embodiment, and a valve 433 installed at the rear end of the air supply unit 420 It may, and may further include a valve 434 installed on the discharge line 470. These valves 431, 432, 433, and 434 may be formed as control valves so as to be controlled by the control unit 450.

The supply line 460 and the discharge line 470 are stored for smooth ventilation in consideration of the fact that the nitrogen gas supplied first to the storage tank 10 has a higher temperature than the air supplied thereafter and has a lower density. By connecting to the lower and upper portions of the tank 10, respectively, nitrogen gas and air can be moved from the lower side to the upper side in the storage tank 10.

The controller 450 may be provided with a timer 451 for counting a set time and a temperature sensor 452 for measuring the temperature of the nitrogen gas heated by the heating unit 440 for gradual heating of nitrogen gas. have.

5 is a block diagram showing an inert and ventilation system of a storage tank according to a fifth embodiment of the present invention.

As shown in FIG. 5, the storage tank inert and venting system 500 according to the fifth embodiment of the present invention includes a nitrogen gas supply unit 510 for supplying nitrogen gas to the storage tank 10, and a storage tank ( 10) an air supply unit 520 for supplying air, an opening/closing unit 530 for opening and closing the supply of nitrogen gas supplied from the nitrogen gas supply unit 510 and air supplied from the air supply unit 520, respectively, and an air supply unit ( A cooling unit 540 that cools air supplied from 530 to the storage tank 10 and a control unit 550 that controls the cooling unit 540 to gradually cool the air may be included.

The storage tank inert and ventilation system 500 according to the fifth embodiment of the present invention gradually cools nitrogen gas to supply the storage tank 10 to the storage tank 10 according to the first embodiment of the present invention. Unlike the system 100, the cooling target differs in that air is gradually cooled by the cooling unit 540 controlled by the control unit 550 and supplied to the storage tank 10, but nitrogen gas and air are Since they are the same as the inert and ventilating system 100 of the storage tank according to the first embodiment in that they have a difference in density from each other, a duplicate description will be omitted.

The opening/closing part 530 includes a valve 531 installed at the rear end of the nitrogen gas supply unit 510 in the supply line 560 and valves 532 and 533 respectively installed at the front and rear ends of the cooling unit 540 as in this embodiment. It may include, and may further include a valve 534 installed in the discharge line 570. These valves 531, 532, 533, and 534 may be formed as control valves to be controlled by the control unit 550.

The supply line 560 and the discharge line 570 are stored to facilitate ventilation in consideration of the fact that the nitrogen gas supplied first to the storage tank 10 has a high temperature and low density compared to the air supplied thereafter. By connecting to the lower and upper portions of the tank 10, respectively, nitrogen gas and air can be moved from the lower side to the upper side in the storage tank 10.

The controller 550 may be provided with a timer 551 for counting a set time and a temperature sensor 552 for measuring a temperature of air cooled by the cooling unit 540 for gradual cooling of air.

6 is a block diagram showing an inert and ventilation system of a storage tank according to a sixth embodiment of the present invention.

As shown in FIG. 6, the storage tank inert and vent system 600 according to the sixth embodiment of the present invention is similar to the storage tank inert and vent system 500 according to the fifth embodiment of the present invention. Nitrogen supplied to the storage tank 10 from the gas supply unit 610, the air supply unit 620, the opening and closing unit 630, the cooling unit 640, and the control unit 650, but additionally nitrogen gas supply unit 610 A heating unit 680 for heating the gas may be further included. Accordingly, the piston effect can be maximized by easily increasing the temperature difference between nitrogen gas and air supplied to the storage tank 10. In this embodiment, the storage tank according to the fourth and fifth embodiments of the present invention A description of the same configuration as the inert and ventilation systems 400 and 500 will be omitted.

As in the present embodiment, the opening and closing unit 630 includes valves 631 and 632 respectively installed at the front and rear ends of the heating unit 680 in the supply line 660 and valves 633 and 634 respectively installed at the front and rear ends of the cooling unit 640. ) May be included, and a valve 635 installed in the discharge line 670 may be further included. These valves 631, 632, 633, 634, and 635 may be formed as control valves to be controlled by the control unit 650.

The control unit 650 controls the heating unit 680 for gradual heating of nitrogen gas and the cooling unit 640 for gradual cooling of air. To this end, the timer 651 and the heating unit 680 Temperature sensors 652 and 653 for measuring temperatures of nitrogen gas heated by) and air cooled by the cooling unit 640 may be further included.

The supply line 660 and the discharge line 670 are stored to facilitate ventilation in consideration of the fact that the nitrogen gas supplied to the storage tank 10 first has a high temperature and low density compared to the air supplied later. By connecting to the lower and upper portions of the tank 10, respectively, nitrogen gas and air can be moved from the lower side to the upper side in the storage tank 10.

In the method of inactivating and venting the storage tank according to the present invention, nitrogen gas for the inert process is supplied to the storage tank 10, and air for the aeration process is supplied to the storage tank 10 after the inert process, but nitrogen gas and The supply temperature of air is different so that nitrogen gas and air have different densities, and specific embodiments will be described below.

The inert and ventilating method of the storage tank according to the first embodiment of the present invention may use, for example, the inert and ventilating system 100 of the storage tank according to the first embodiment of the present invention. That is, an inert step of gradually cooling nitrogen gas supplied from the nitrogen gas supply unit 110 by the cooling unit 140 and supplying it to the storage tank 10 so that the nitrogen gas is filled in the storage tank 10, and storage It may include a venting step of supplying air to the tank 10 from the air supply unit 110 and replacing nitrogen gas with air in the storage tank 10.

The gradual cooling of the nitrogen gas in the inert step can be performed by the control unit 150 controlling the cooling unit 140, and for the inert step and the aeration step, the control unit 150 is the opening and closing unit ( 130).

In addition, in the inert step and the aeration step, nitrogen gas and air may be respectively supplied to the upper portion of the storage tank 10 through a supply line 160 connected to the upper portion of the storage tank 10, and the storage tank 10 The nitrogen gas and air in the storage tank 10 may be discharged through the discharge line 170 connected to the lower portion of the storage tank 10. Therefore, since the nitrogen gas supplied to the storage tank 10 first has a higher density than the air supplied afterwards due to cooling, the air in the storage tank 10 can be smoothly replaced with the nitrogen gas.

The inert and ventilating method of the storage tank according to the second embodiment of the present invention may use, for example, the inert and ventilating system 200 of the storage tank according to the second embodiment of the present invention, and from the nitrogen gas supply unit 210 An inert step of supplying nitrogen gas to the storage tank 10 so that nitrogen gas is filled in the storage tank 10, and the air supplied from the air supply unit 220 to the storage tank 10 by the heating unit 240 It may include a venting step of replacing nitrogen gas with air in the storage tank 10 by gradually heating and supplying it.

In the aeration step, the gradual heating of the air may be performed by the control unit 250 controlling the heating unit 240, and the sequential supply of nitrogen gas and air for the inert step and the aeration step is performed by the control unit 250 230).

In addition, in the inert step and the aeration step, nitrogen gas and air may be respectively supplied to the upper portion of the storage tank 10 through a supply line 260 connected to the upper portion of the storage tank 10, and the storage tank 10 The nitrogen gas and air within the storage tank 10 may be discharged through the discharge line 270 connected to the lower portion of the storage tank 10. Therefore, the nitrogen gas supplied to the storage tank 10 first has a higher density than the heated air supplied thereafter, so that the air in the storage tank 10 can be smoothly replaced with the nitrogen gas.

The inert and ventilating method of the storage tank according to the third embodiment of the present invention may use, for example, the inert and ventilating system 300 of the storage tank according to the third embodiment of the present invention, and the second embodiment of the present invention The storage tank according to the second embodiment of the present invention is the same as the method of inactivating and venting the storage tank according to, but in the inert step, nitrogen gas is gradually cooled by the cooling unit 380 and supplied to the storage tank 10. Since there is a difference from the method of inert and ventilating the tank, redundant descriptions excluding this will be omitted.

In addition, since the gradual cooling of nitrogen gas has been described in the method of inactivating and venting the storage tank according to the first embodiment of the present invention, redundant descriptions will be omitted. Therefore, it is possible to easily increase the density difference between the nitrogen gas and air supplied to the storage tank 10, thereby maximizing the piston effect in the venting step.

The inert and venting method of the storage tank according to the fourth embodiment of the present invention can be used, for example, the inert and venting system 400 of the storage tank according to the fourth embodiment of the present invention, from the nitrogen gas supply unit 410 An inert step of gradually heating the supplied nitrogen gas by the heating unit 440 and supplying it to the storage tank 10 to fill the storage tank 10 with nitrogen gas, and an air supply unit 420 to the storage tank 10 It may include a venting step of supplying air from) and replacing nitrogen gas with air in the storage tank 10.

The gradual heating of the nitrogen gas in the inert step can be performed by the control unit 450 controlling the heating unit 440, and for the sequential supply of nitrogen gas and air for the inert step and the aeration step, the control unit 450 uses the opening and closing unit ( This can be done by controlling 430).

In addition, in the inert step and the aeration step, nitrogen gas and air may be supplied to the lower portion of the storage tank 10 through a supply line 460 connected to the lower portion of the storage tank 10, respectively, and the storage tank 10 ) In the nitrogen gas and air can be discharged through the discharge line 470 connected to the upper portion of the storage tank (10). Therefore, since the nitrogen gas supplied to the storage tank 10 first has a lower density than the air supplied afterwards due to heating, the air in the storage tank 10 can be smoothly replaced with the nitrogen gas.

The inert and ventilating method of the storage tank according to the fifth embodiment of the present invention can use, for example, the inert and ventilating system 500 of the storage tank according to the fifth embodiment of the present invention, from the nitrogen gas supply unit 510 An inert step of supplying nitrogen gas to the storage tank 10 so that nitrogen gas is filled in the storage tank 10, and the air supplied from the air supply unit 520 to the storage tank 10 by the cooling unit 540 By gradually cooling and supplying, it may include an aeration step of replacing nitrogen gas with air in the storage tank 10.

In the aeration step, the gradual cooling of the air may be performed by the control unit 550 controlling the cooling unit 540, and the sequential supply of nitrogen gas and air for the inert step and the aeration step is performed by the control unit 550 530).

In addition, in the inert step and the aeration step, nitrogen gas and air may be supplied to the lower portion of the storage tank 10 through a supply line 560 connected to the lower portion of the storage tank 10, respectively, and the storage tank 10 ) In the nitrogen gas and air can be discharged through the discharge line 570 connected to the upper portion of the storage tank (10).

Accordingly, the nitrogen gas supplied to the storage tank 10 first has a lower density than the cooled air supplied thereafter, so that the air in the storage tank 10 can be smoothly replaced with the nitrogen gas.

The method of inactivating and venting the storage tank according to the sixth embodiment of the present invention may use, for example, the inert and ventilating system 600 of the storage tank according to the sixth embodiment of the present invention, and the fifth embodiment of the present invention Storage according to the fifth embodiment of the present invention in that it is the same as the method of inactivating and venting the storage tank according to, but gradually heating nitrogen gas by the heating unit 680 in the inert step and supplying it to the storage tank 10. Since there is a difference from the method of inert and ventilating the tank, a redundant description excluding this will be omitted.

In addition, since the gradual heating of nitrogen gas has been described in the method of inactivating and venting the storage tank according to the fourth embodiment of the present invention, a duplicate description will be omitted. Therefore, it is possible to easily increase the density difference between the nitrogen gas and air supplied to the storage tank 10, thereby maximizing the piston effect in the venting step.

Meanwhile, in the method of inactivating and venting the storage tank according to the present invention, a step of emptying the storage material in the storage tank before the inactivation step and evaporating the residue through a warm-up process may be performed.

In addition, after the maintenance and repair are completed by making the storage tank 10 have an environment suitable for maintenance and repair through the inert and aeration steps, the storage tank 10 is re-inactive before storing the storage in the storage tank. ) Steps to minimize the amount of air remaining inside can be performed.

As described above, according to the present invention, nitrogen gas and air are respectively used for inactivation and ventilation of the storage tank 10, thereby preventing the effect of freezing when operating at a low temperature, and nitrogen gas and air are heated or By cooling to have a difference in density, it is possible to exert a piston effect upon replacement.

In addition, by gradually heating or cooling nitrogen gas or air to be supplied to the storage tank 10, it is possible to prevent a decrease in density difference due to thermal equilibrium inside the storage tank 10, thereby reducing the piston effect. By maximizing it, inactivation and ventilation of the storage tank 10 can be made smoothly.

It is apparent to those of ordinary skill in the art that the present invention is not limited to the above embodiments, and can be variously modified or modified within the scope not departing from the technical gist of the present invention. I did it.

10: storage tank
110,210,310,410,510,610: nitrogen gas supply unit
120,220,320,420,520,620: Air supply unit
130,230,330,430,530,630: opening and closing part
140,380,540,640: cooling unit
150,250,350,450,550,650: control unit
151,251,351,451,551,651: Timer
152,252,352,353,452,552,652,653: Temperature sensor
160,260,360,460,560,660: Supply line
170,270,370,470,570,670: discharge line
240,340,440,680: heating part

Claims (17)

In the system for performing inert and aeration for the storage tank,
A nitrogen gas supply unit supplying nitrogen gas to the storage tank;
An air supply unit supplying air to the storage tank; And
Including; an opening and closing unit for opening and closing the supply of the nitrogen gas supplied from the nitrogen gas supply unit and the air supplied from the air supply unit, respectively,
A cooling unit for cooling nitrogen gas supplied to the storage tank from the nitrogen gas supply unit; And
A heating unit for heating air to be supplied to the storage tank from the air supply unit; It further includes any one or more of,
Inert and venting system of a storage tank comprising a control unit for controlling the temperature of at least one of the nitrogen gas and air to be gradually changed and supplied so that thermal equilibrium does not occur in the storage tank. delete delete delete In the system for performing inert and aeration for the storage tank,
A nitrogen gas supply unit supplying nitrogen gas to the storage tank;
An air supply unit supplying air to the storage tank; And
Including; an opening and closing unit for opening and closing the supply of the nitrogen gas supplied from the nitrogen gas supply unit and the air supplied from the air supply unit, respectively,
A heating unit for heating nitrogen gas to be supplied to the storage tank from the nitrogen gas supply unit; And
A cooling unit that cools air supplied to the storage tank from the air supply unit; It further includes any one or more of,
Inert and venting system of a storage tank comprising a control unit for controlling the temperature of at least one of the nitrogen gas and air to be gradually changed and supplied so that thermal equilibrium does not occur in the storage tank. delete delete delete In the method of performing inert and aeration for the storage tank,
An inert step of supplying nitrogen gas to the storage tank so that the nitrogen gas is filled in the storage tank; And
Aeration step of supplying air to the storage tank and replacing nitrogen gas with air in the storage tank; including,
A cooling step of cooling nitrogen gas supplied to the storage tank; And
A heating step of heating the air supplied to the storage tank; It further includes any one or more of,
A method of inactivating and venting the storage tank by gradually changing the temperature of at least one of the nitrogen gas and air so that thermal equilibrium does not occur in the storage tank. delete delete delete In the method of performing inert and aeration for the storage tank,
An inert step of supplying nitrogen gas to the storage tank so that the nitrogen gas is filled in the storage tank; And
Aeration step of supplying air to the storage tank and replacing nitrogen gas with air in the storage tank; including,
A heating step of heating nitrogen gas supplied to the storage tank; And
A cooling step of cooling the air supplied to the storage tank; It further includes any one or more of,
A method of inactivating and venting the storage tank by gradually changing the temperature of at least one of the nitrogen gas and air so that thermal equilibrium does not occur in the storage tank. delete delete delete delete

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