KR20190062963A - Cryogenic storage tank for liquefied natural gas and this filled method - Google Patents

Abstract

Provided is a cryogenic liquefied gas storage tank comprising a tank body which stores cryogenic liquefied gas and supplies the cryogenic liquefied gas to a factory which uses the cryogenic liquefied gas, and an auxiliary tank which forms a space separated from the tank body inside the tank body and is extended to an upper part of the tank body with a diameter smaller than an inner diameter of the tank body. The present invention maintains a high hydraulic head pressure constant when filling the cryogenic liquefied gas sold to the outside, thereby being capable of predicting a filling time of a tank lorry so as to efficiently supply with the cryogenic liquefied gas.

Description

Technical Field [0001] The present invention relates to a cryogenic liquefied gas storage tank and a cryogenic gas storage tank,

A storage tank for storing cryogenic liquefied gas and supplying it to an outside company through a tank lorry.

Generally, the storage tank for storing the cryogenic liquefied gas is required to keep the inside of the tank at a cryogenic temperature, thereby preventing thermal contact such as radiation, convection, and conduction with the outside air.

Accordingly, the ultra low temperature liquefied gas storage tank doubles the tank wall surface outwardly and inwardly, and performs heat insulation treatment therebetween. In order to insulate the storage tank, filler powder is filled between the outer side and the inner side of the tank wall surface and nitrogen gas is sealed. Nitrogen gas is filled in the spaces between the fillet powder powders to have an excellent heat insulating effect.

Liquid oxygen, liquid nitrogen, and liquid argon in the cryogenic (-187 to -196 ° C) state stored in the storage tank are compressed by a pump according to operating conditions and vaporized by a gas at room temperature by a vaporizer. Vaporized gas is supplied to the steelworks. The excess cryogenic liquefied gas remaining in the storage tank is supplied to the tank lorry and sold to the industrial site for various purposes.

The cryogenic liquefied gas storage level of the storage tank may be supplied to the plant in excess of the cryogenic liquefied gas volume produced according to the operating mode of the plant in use, and may be stored in the storage tank in the normal operating condition do.

In other words, the cryogenic liquefied gas storage level of the storage tank may be 100% depending on the operating condition of the factory of the use place. There is a case where the cryogenic liquefied gas storage level is 20% or less by using a cryogenic liquefied gas stored in the storage tank in a short period of time in order to cope with a shortage of the gas supply amount when the specific air separation apparatus of the oxygen plant breaks abruptly .

Since the cryogenic liquefied gas storage level varies greatly as described above, the head head pressure deviation is large when the cryogenic liquefied gas in the storage tank is supplied to the tank. If the water head pressure is high, cryogenic liquefied gas of the storage tank can be supplied to the tank lorry in a short time. On the other hand, if the water head pressure is low, the cryogenic liquefied gas of the storage tank can be supplied to the tank lately.

There is a problem in that a time deviation in supplying the cryogenic liquefied gas to the tank lorry is large according to the water head pressure difference of the storage tank. It is difficult to predict the filling time due to the supply time deviation of the cryogenic liquefied gas, and it is difficult for the customer to supply the product at a desired time.

Also, when the cryogenic liquefied gas storage level of the storage tank is lowered to a predetermined value or lower, a phenomenon may occur that the pump can not be started due to a decrease in the effective suction head. Accordingly, the cryogenic liquefied gas can not be supplied to the tank lorry until the effective suction head is raised to a predetermined level or higher in the storage tank. There is a problem in that the cryogenic liquefied gas is discontinued due to the cessation of the supply of the cryogenic liquefied gas and the supply of cryogenic liquefied gas at the customer's company becomes difficult due to abrupt sales interruption.

The present invention provides a cryogenic liquefied gas storage tank and a filling method for efficiently supplying cryogenic liquefied gas by making it possible to predict the filling time of the tank lorry by keeping the high head pressure constant while charging the cryogenic liquefied gas sold to the outside.

The cryogenic liquefied gas storage tank includes a tank body for storing cryogenic liquefied gas and supplying the cryogenic liquefied gas to a factory for consuming the cryogenic liquefied gas, and a space separated from the tank body inside the tank body, and having a diameter smaller than the inner diameter of the tank body, And an auxiliary tank extending to the top.

The auxiliary tank is structured such that a lower end thereof is closed and an upper end thereof is opened, and the auxiliary tank is installed at a central portion of the tank body.

The cryogenic liquefied gas storage tank has a structure in which a supply pipe for supplying cryogenic liquefied gas to the tank body is connected to the auxiliary tank to supply cryogenic liquefied gas to the tank.

The cryogenic liquefied gas storage tank is a structure in which the cryogenic liquefied gas supplied to the auxiliary tank first fills the auxiliary tank and overflows and is filled in the tank body.

The tank body may further include a fixing bracket installed at the bottom portion and fixing the lower portion of the auxiliary tank.

The auxiliary tank is installed in the tank body so as to be detachably attached to the fixing bracket.

The auxiliary tank has a structure in which the cryogenic liquefied gas storage level is maintained at 100% when cryogenic liquefied gas is supplied to the tank lorry.

The tank body is a structure in which the storage level of the cryogenic liquefied gas varies depending on the operation rate of the plant when cryogenic liquefied gas is supplied to the plant.

The cryogenic liquefied gas filling method comprises the steps of preparing a storage tank having a tank body for storing liquefied gas and an auxiliary tank provided in the tank body and having a smaller volume than the tank body; The liquefied gas in the auxiliary tank is filled with the external tanker, the liquefied gas in the tank body is supplied to the necessary process through the separate supply line, . ≪ / RTI >

According to this apparatus, it is possible to supply cryogenic liquefied gas more efficiently to the tank factory of the steelworks and the outside company by differentiating the storage tank. When charging cryogenic liquefied gas to tanker of external company, it is possible to maintain constant tank head pressure and constant filling time of tank.

Furthermore, by maintaining the cryogenic liquefied gas filling time of the tank lor constant, it is possible to improve the reliability of the filling operation and product supply. The filling time of the tank can be minimized by keeping the head pressure of the tank constantly high.

1 is a view schematically showing a cryogenic liquefied gas storage tank according to the present embodiment.
2 is a view schematically showing the cryogenic liquefied gas storage level of the storage tank according to the present embodiment.
3 is a view showing a state in which the cryogenic liquefied gas storage level of the storage tank according to the present embodiment is variable.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

1 is a view schematically showing a cryogenic liquefied gas storage tank according to the present embodiment.

Liquid oxygen, liquid nitrogen, and liquid argon, which are cryogenic liquefied gases produced in an air separation unit (not shown), are stored in the cryogenic liquefied gas storage tank 1 through the supply pipe 2, as shown in Fig. do.

The cryogenic liquefied gas stored in the cryogenic liquefied gas storage tank 1 is supplied to each plant 3 of the steelworks or to the tanker 4 for sale to an external gas company.

The storage tank 1 includes a tank body 10 provided to store the cryogenic liquefied gas and supply it to a factory 3 that consumes the cryogenic liquefied gas and a tank body 10 disposed inside the tank body 10. [ 10 and an auxiliary tank 20 extending to an upper portion of the tank body 10 with a diameter smaller than the inner diameter of the tank body 10. [

In addition, the auxiliary tank 20 has a structure in which a lower end thereof is closed and an upper end thereof is opened, and the auxiliary tank 20 is installed at a central portion of the tank body 10. The auxiliary tank 20 is installed inside the tank body 10 in the form of a separate container. The auxiliary tank 20 is vertically disposed at the center of the storage tank 1.

The storage tank 1 has a structure in which a supply pipe 2 for supplying cryogenic liquefied gas to the tank body 10 is connected to the auxiliary tank 20 to supply cryogenic liquefied gas to the tank. The auxiliary tank 20 and the tank 4 are connected to supply the cryogenic liquefied gas from the auxiliary tank 20 to the tank 4.

The storage tank 1 is a dual structure of a tank body 10 for supplying cryogenic liquefied gas to the factory 3 and an auxiliary tank 20 for supplying the tank 3 to the tank. The auxiliary tank 20 is installed in the center of the tank body 10 and the tank body 10 and the auxiliary tank 20 are filled with cryogenic liquefied gas.

That is, the cryogenic liquefied gas storage tank 1 is configured such that the cryogenic liquefied gas supplied to the auxiliary tank 20 through the supply pipe 2 first fills the auxiliary tank 20 and flows over the tank body 10 Structure.

The outlet 2a of the supply pipe 2 is disposed on the upper portion of the auxiliary tank 20 so that the cryogenic liquefied gas supplied from the supply pipe 2 first fills the auxiliary tank 20. [ When the cryogenic liquefied gas is completely filled in the auxiliary tank 20, the cryogenic liquefied gas then flows over from the auxiliary tank 20 to fill the inside of the tank body 10 outside the auxiliary tank 20.

When the cryogenic liquefied gas is completely filled up to the inside of the tank body 10, the cryogenic liquefied gas supply of the supply pipe 2 is cut off. In this case, the cryogenic liquefied gas storage level (L) of the auxiliary tank (20) and the cryogenic liquefied gas storage level (L1) of the tank body (10)

The auxiliary tank 20 can supply cryogenic liquefied gas to the tank 4 through the supply pipe 2. The auxiliary tank 20 maintains the storage level L filled with 100% when the cryogenic liquefied gas is supplied to the tank 4, so that the cryogenic liquefied gas can be supplied at a constant rate. Since the cryogenic liquefied gas is supplied to the tank 4 at a constant rate, the operator can predict the supply time of the cryogenic liquefied gas.

Since the supply time of the cryogenic liquefied gas can be predicted as described above, it is possible to improve the reliability with the customer when selling the cryogenic liquefied gas. The liquefied gas can be more effectively supplied to the tank factory 4 of the steelmaker and the outside of the steelmaking plant by differentiating the storage tank 1.

In addition, the cryogenic liquefied gas stored in the tank body 10 of the storage tank 1 can be supplied to each factory 3 of the steelworks. The ultra-low temperature liquefied gas stored in the tank body 10 is compressed by a pump 5 and is vaporized by a vaporizer 6 at a room temperature to supply gas to each factory 3 that requires gas.

The cryogenic liquefied gas storage level (L1) of the tank body (10) varies according to the operation rate of the factory (3). The greater the amount of cryogenic liquefied gas used, the lower the storage level L1. When the storage level (L1) becomes low enough that the pump (5) can not be operated, the cryogenic liquefied gas is supplied to the auxiliary tank (20) of the storage tank (1). The cryogenic liquefied gas flowing from the auxiliary tank (20) replenishes the tank body (10).

Therefore, in order to fill the tank body 10 with cryogenic liquefied gas, it is necessary to fill the auxiliary tank 20 with cryogenic liquefied gas in advance, so that the storage level L of the auxiliary tank 20 can always be maintained at 100% have.

The storage tank 1 may further include a fixing bracket 30 installed at the bottom of the tank body 10 to fix the lower portion of the auxiliary tank 20. The auxiliary tank 20 is detachably attached to the fixing bracket 30 inside the tank body 10.

The auxiliary tank 20 can be held in the tank body 10 by the fixing bracket 30. The auxiliary tank 20 may be detachably installed in the tank body 10 for maintenance and maintenance of the storage tank 1.

2 is a view schematically showing the cryogenic liquefied gas storage level of the storage tank according to the present embodiment. 3 is a view showing a state in which the cryogenic liquefied gas storage level of the storage tank according to the present embodiment is variable.

As shown in FIGS. 2 and 3, the auxiliary tank 20 has a structure in which the storage level L of the cryogenic liquefied gas is maintained at 100% when the cryogenic liquefied gas is supplied to the tank 4. The storage level L of the cryogenic liquefied gas in the auxiliary tank 20 is 100%, which means that the cryogenic liquefied gas is filled in the auxiliary tank 20. This means that the head of the cryogenic liquefied gas maintains the highest state.

As described above, in the auxiliary tank 20, the cryogenic liquefied gas is supplied to the tank 4 in the best condition of the water head pressure at which the cryogenic liquefied gas storage level L is 100%. As a result, the tank lorry 4 can be filled with cryogenic liquefied gas in the shortest time. The supply time can be constantly maintained by supplying the cryogenic liquefied gas at a state where the storage level (L) of the cryogenic liquefied gas is always 100%.

Since the time to fill the tank lorry 4 with the cryogenic liquefied gas can be predicted, it is possible for the cryogenic liquefied gas suppliers to predict the supply schedule with the customer and to establish the sales plan stably.

The tank body 10 has a structure in which the storage levels L1, L2 and L3 of cryogenic liquefied gas are varied according to the operation rate of the factory 3 when cryogenic liquefied gas is supplied to the factory 3. The storage level of the cryogenic liquefied gas stored in the tank body 10 may be 50% (L2) and the storage level L3 may be 30% depending on the amount of gas used in the plant 3 .

As described above, the storage levels (L1, L2, L3) of the ultra-low temperature liquefied gas in the tank body 10 change from time to time depending on the supply amount of the gas. Temperature liquefied gas is supplied to the storage tank 1 at a point in time when it becomes impossible to operate the pump 5 for gas supply due to the continuous decrease of the storage levels L1, L2 and L3.

As the cryogenic liquefied gas is supplied to the storage tank 1, the auxiliary tank 20 is filled with the cryogenic liquefied gas, and then the tank body 10 is filled with the cryogenic liquefied gas.

Accordingly, when the cryogenic liquefied gas is supplied to the tank 4, the supply of the cryogenic liquefied gas can be started while maintaining the storage level L of the cryogenic liquefied gas at 100%. The filling time of the tank 4 can be made constant by keeping the water head pressure of the storage tank 1 constant when filling the tank 4 with the cryogenic liquefied gas.

The cryogenic liquefied gas filling method comprises a tank body 10 for storing liquefied gas and a storage tank 20 provided in the tank body 10 and having a smaller volume than the tank body 10 A step of supplying a liquefied gas to the auxiliary tank 20 and supplying a liquefied gas to the tank body 10 when a portion exceeding the supply of the liquefied gas is supplied to the auxiliary tank 20, The liquefied gas is filled with the external tanker 4, and the liquefied gas in the tank body 10 is introduced into the necessary process through the separate supply line.

The liquefied gas stored in the auxiliary tank 20 can be filled into the tank lorry 4 through the cryogenic liquefied gas filling method. A certain amount of liquefied gas is always stored in the auxiliary tank 20 and the liquefied gas can be filled into the tank lorry 4 within a predetermined time.

Also, the liquefied gas stored in the tank body 10 can be supplied to a separate supply line through the cryogenic liquefied gas filling method to a process requiring liquefied gas.

To this end, the storage tank 1 in which the liquefied gas is stored may be divided into a tank body 10 and an auxiliary tank 20. The tank body (10) stores liquefied gas supplied to a factory (3) for product production. Liquefied gas to be supplied to the tank lorry 4 is stored in the auxiliary tank 20.

Therefore, by maintaining the cryogenic gas filling time of the cryogenic tank 4 constant, it is possible to improve the reliability of the filling operation and the supply of the product during the filling operation. By keeping the water head pressure of the storage tank 1 always high, 4) can be minimized.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

1: storage tank 2: supply pipe
2a: Exit 3: Factory
4: Tank Lorry 5: Pump
6: carburetor 10: tank body
20: auxiliary tank 30: fixed bracket
L, L1, L2, L3: storage level

Claims (10)

A tank body for storing cryogenic liquefied gas and supplying it to a plant that consumes it, and
And an auxiliary tank formed inside the tank body and separated from the tank body and extending to an upper portion of the tank body with a diameter smaller than an inner diameter of the tank body. The method according to claim 1,
Wherein the ultra low temperature liquefied gas supplied to the tank body and the auxiliary tank comprises liquid oxygen, liquid nitrogen, and liquid argon. The method according to claim 1,
Wherein the auxiliary tank is closed at a lower end thereof and opened at an upper end thereof to a central portion of the tank body. The method of claim 3,
And a supply pipe for supplying cryogenic liquefied gas to the tank body is connected to the auxiliary tank to supply cryogenic liquefied gas to the tank. 5. The method of claim 4,
Wherein the cryogenic liquefied gas supplied to the auxiliary tank first fills and flows over the auxiliary tank and is filled in the tank body. The method according to claim 1,
Wherein the tank body further includes a fixing bracket installed at a bottom portion and fixing a lower portion of the auxiliary tank. The method according to claim 6,
And the auxiliary tank is detachably installed in the fixing bracket within the tank body. 5. The method of claim 4,
Wherein the auxiliary tank maintains a storage level of cryogenic liquefied gas at 100% when the cryogenic liquefied gas is supplied to the tank lorry. The method according to claim 1,
Wherein the tank body varies the storage level of the cryogenic liquefied gas according to the operation rate of the plant when the cryogenic liquefied gas is supplied to the plant. Preparing a storage tank having a tank body for storing the liquefied gas and an auxiliary tank provided in the tank body and having a smaller volume than the tank body;
Supplying the liquefied gas to the auxiliary tank first, and supplying the liquefied gas to the tank body when the excess portion is overflowed;
Filling the liquefied gas in the auxiliary tank with an external tank lorry; And
Wherein the liquefied gas in the tank body is supplied through a separate feed line to a necessary process.

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