JP2006069639A - Floating cover type storage tank - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a floating cover type storage tank (1) capable of storing liquid (A) in a tank main body (2) while sufficiently mixing it in the tank. <P>SOLUTION: A floating cover type storage tank (1) of this invention is constructed such that an ascending flow (S1) ascending from a bottom surface (22) along a side wall (21) is formed in liquid (A) in a tank main body over its entire circumference, wherein this ascending flow (S1) becomes a horizontal flow (S2) flowing along a lower surface (3a) of the floating cover from the side wall (21) toward an axis of center of gravity (L), this horizontal flow (S2) is merged with the ascending flow near the axis of center of gravity (L) to form another descending flow (S3) descending along the axis of center of gravity (L). Normally, an injection nozzle (4) is installed near the axis of center of gravity (L) at the bottom surface (22), liquid (A) is injected from the injection nozzle (4) toward the side wall (21) to form a bottom surface flow (S4) along the bottom surface (22) toward the side wall (21) and then this bottom surface flow (S4) becomes the ascending flow (S1). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a floating roof storage tank.

As shown in FIG. 4 (a), a liquid tank (A) is provided as a storage tank having a cylindrical tank body (2) placed vertically and storing the liquid (A) inside the tank body (2). A floating roof type storage tank (1) provided with a floating roof (3) floated on the liquid surface is widely used [Patent Document 1: Japanese Patent Laid-Open No. 9-142575, etc.]. In this tank (1), the liquid (A0) for storage is received from the inlet provided near the bottom surface (22) of the tank body (2), and from the outlet provided near the bottom surface (22), The liquid (A) stored inside is extracted. When the amount of stored liquid (A) increases or decreases due to the balance between the amount of liquid received and the amount of liquid extracted, and the liquid level rises and falls, the floating roof (3) also rises and falls accordingly.

By the way, it is desirable that the liquid (A) stored in the storage tank (1) is stored with stirring for the purpose of uniformizing the liquid temperature.

In the storage tank (1 ′) not provided with the floating roof (3), as shown in FIG. 4B, the injection nozzle (4) for injecting the liquid (A) in one direction is provided on the bottom surface (22 ), And by injecting the liquid (A) from the injection nozzle (4) toward the side wall (21), the liquid (A) is circulated throughout the entire area of the tank body (2). A storage tank (1 ') for mixing is known [Patent Document 2: Japanese Patent Laid-Open No. 7-119888].

However, in the floating roof storage tank (1), if the liquid (A) inside is to be mixed sufficiently, the floating roof (3) floating on it will inadvertently collide with the side wall (21). It is preferable to store the liquid (A) in a state of being kept as static as possible because of dripping.

JP-A-9-142575 Japanese Patent Laid-Open No. 7-11988

Therefore, as a result of intensive studies to develop a floating roof type storage tank (1) capable of storing the liquid (A) while being sufficiently mixed, the inventor of the liquid (A) in the tank body (2) has a side wall ( 21), an upward flow (S1) rising from the bottom surface (22) is formed along the entire circumference, and this upward flow (S1) extends along the lower surface (3a) of the floating roof (3). The horizontal flow (S2) from the side wall (21) toward the center of gravity axis (L) of the floating roof (3), merges near the center of gravity axis (L), and descends along this axis (L) ( By configuring so as to form (S3), the internal liquid (A) can be sufficiently mixed by these upward flow, horizontal flow and downward flow (S1 to S3), and along the floating roof lower surface (3a) The horizontal flow (S2) joins in the vicinity of the center of gravity axis (L) and descends along the axis (L), so it can be found that the floating roof (3) can be prevented from violently colliding with the side wall (21), The present invention has been reached.

That is, the present invention is a vertical cylindrical tank body (2),
A floating roof (3) floated on the liquid level of the liquid (A) stored in the tank body,
The liquid (A) forms an upward flow (S1) rising from the bottom surface (22) along the side wall (21) along the entire circumference of the side wall (21) of the tank body,
The upward flow (S1) becomes a horizontal flow (S2) from the side wall (21) toward the center of gravity axis (L) of the floating roof (3) along the lower surface (3a) of the floating roof (3),
The floating roof is configured so that the horizontal flow (S2) merges in the vicinity of the gravity center axis (L) to form a downward flow (S3) descending along the gravity center axis (L) A storage tank (1) is provided. FIG. 1 schematically shows an example of the floating roof type storage tank (1) of the present invention.

According to the floating roof type storage tank (1) of the present invention, the floating roof (3) can be prevented from colliding with the side wall while sufficiently mixing the liquid (A) stored therein.

Hereinafter, the floating roof type storage tank (1) of the present invention will be described with reference to FIGS. 1 to 3 are diagrams schematically showing a floating roof type storage tank (1) according to the present invention. FIG. 1 is a longitudinal sectional view, and FIG. FIG. 3 is a cross-sectional view showing the flow of (A), and FIG. 3 is a cross-sectional view showing the flow of liquid (A) near the bottom surface (22).

As shown in FIG. 1, the floating roof type storage tank (1) of the present invention stores the liquid (A) in the tank body (2). The shape of the tank body (2) is a vertical cylindrical shape placed vertically, and is usually cylindrical, and its inner diameter (d) is usually about 5 to 50 m, and the height (h0) is Usually, it is about 5 m to 20 m. As shown in FIG. 1, the tank body (2) may be a floating roof tank with a fixed roof having a closed top and hermetically sealed, or a floating roof tank having a structure with an open top and no fixed roof. It may be.

The floating roof type storage tank (1) of the present invention includes a floating roof (3). This floating roof (3) is floated on the liquid surface of the liquid (A) stored in the tank body. The floating roof (3) is usually a hollow structure made of a material such as steel or aluminum, and is preferably made of aluminum because of its light weight. The shape of the floating roof (3) is usually a plate shape, and is a disk shape that matches the cross-sectional shape of the tank body (2). This floating roof (3) floats on the liquid level of the liquid (A) inside, and if the liquid level rises and falls due to increase or decrease in the storage amount of the liquid (A), the floating roof (3) It moves up and down along the side wall (21) of the tank body. The liquid depth (h) indicated as the height of the liquid surface from the bottom surface (22) varies depending on the size of the tank body (2), but is usually about 1 to 15 m.

As shown in FIGS. 1 and 2, the floating roof type storage tank (1) of the present invention has an upward flow rising from the bottom surface (22) along the side wall (21) of the tank body to the liquid (A) inside. (S1) is formed.

Such an upward flow (S1) is usually provided with an injection nozzle (4) on the bottom surface (22) of the tank body (2), and liquid (A) from the injection nozzle (4) toward the side wall (21). ). As shown in FIG. 3, the spray nozzle (4) is provided in the vicinity of the center of gravity axis (L) of the floating roof. The center of gravity axis (L) is a vertical axis that passes through the center of gravity (30) of the floating roof (3). By injecting the liquid (A) from the injection nozzle (4), a bottom surface flow (S4) directed toward the side wall (21) along the bottom surface (22) is formed. When this bottom surface flow (S4) reaches the side wall (21), it becomes an upward flow (S1) that rises along this side wall (21).

A plurality of spray nozzles (4) are provided radially about the center of gravity axis (L) so that the liquid (A) can be sprayed toward the entire circumference of the side wall (21). The number of spray nozzles (4) may be two or nine or more, but is four or more in that the floating roof (3) can be more reliably prevented from colliding with the side wall (21). However, it is preferably 8 or less, and more preferably 6 or less in that it is easy to obtain an effect commensurate with the number.

The liquid (A) ejected from the ejection nozzle (3) can be used by, for example, refluxing the liquid (A) extracted from the tank body (2), and then adjusting the temperature by heating or cooling. Then, it may be ejected from the ejection nozzle. A liquid (A0) fed from the outside for storing in the storage tank (1) may be used. As long as the bottom surface flow (S4) toward the side wall (21) can be formed along the bottom surface (22), the spray direction may be sprayed in a horizontal direction parallel to the bottom surface (22), or obliquely. You may inject upwards. The flow rate of the liquid sprayed from the spray nozzle (4) is the size of the tank body (2), such as the inner diameter (d) and height (h), the depth of the liquid (A), the viscosity, and the spray from the spray nozzle. Although it varies depending on the amount, the target degree of mixing, the distance from the injection nozzle to the side wall, etc., it is preferably as high as possible because the liquid (A) stored inside can be entrained and mixed efficiently. It is about 15 m / sec.

The upward flow (S1) thus formed reaches the lower surface (3a) of the floating roof, where it becomes a horizontal flow (S2). This horizontal flow (S2) is a flow from the side wall (21) toward the center of gravity axis (L) along the lower surface (3a) of the floating roof. The flow rate of the horizontal flow (S2) can be adjusted by, for example, the flow rate from the injection nozzle (4), the injection amount, the distance from the injection nozzle to the side wall, and the like, for example, 1 m / second or less.

The horizontal flow (S2) travels from the entire circumference of the side wall (21) toward the center of gravity axis (L) and collects on the center of gravity axis (L). The horizontal flow (21) collected on the center of gravity axis joins to form a downward flow (S3). The floating roof type storage tank (1) of the present invention is configured such that the downward flow (S3) descends along the center of gravity axis (L). For this configuration, for example, a horizontal flow (S2) from the entire circumference of the side wall (21) toward the center of gravity axis (L) with a uniform flow velocity may be formed. The liquid (A) may be sprayed uniformly from the spray nozzle (4) toward the side wall (21) so that an upward flow (S1) with a uniform flow velocity is formed over the circumference.

  In the floating roof type storage tank (1) of the present invention, sufficient agitation is possible, so that the liquid (A) to be stored is thoroughly mixed to make the liquid temperature uniform, uniform concentration, and sludge accumulation. Prevention is possible.

EXAMPLES Hereinafter, although an Example demonstrates this invention in detail, this invention is not limited by this Example.

Example 1
A liquid (A) having a density (ρ) of 840 kg / m ³ and a viscosity (η) of 0.00031 Pa · s is applied to a tank body (2) having an inner diameter (d) of 15580 mm as shown in FIG. When the liquid (A) is stored and sprayed from the spray nozzle (4) provided on the bottom surface (22) toward the side wall (21) in the horizontal direction, the flow of the liquid (A) inside the tank body (2) Obtained by simulation.

The number of the injection nozzles (4) was six, and the adjacent injection nozzles (4) were arranged at an angle of 60 degrees. The distance from the tip of the injection nozzle (4) to the side wall (21) was 7790 mm. The height from the bottom surface (22) to the injection nozzle (4) was 600 mm. The flow rate of the liquid (A) ejected from the ejection nozzle (4) was set to 6.1 m / second. The total amount of liquid sprayed from the spray nozzle (4) was 22 m ³ / hour.

As a result of the simulation, the flow rate of the upward flow (S1) rising in the vicinity of the side wall (21) is 2676 m ³ / hour, and the liquid (A) can be sufficiently stirred in the tank body (2). Moreover, the maximum value of the flow velocity of the horizontal flow (S2) on the lower surface (3a) of the floating roof is 0.037 m / sec, and there is no possibility that the floating roof (3) will move carelessly.

Example 2
There are four injection nozzles (4), the angle formed by the adjacent injection nozzles (4) is 90 degrees, the distance from the tip of the injection nozzle (4) to the side wall (21) is 6290 mm, and the injection nozzle is from the bottom surface (22). The simulation was performed under the same conditions as in Example 1 except that the height up to (4) was 300 mm and the flow rate of the liquid (A) from the spray nozzle (4) was 5.6 m / sec. As a result, the flow rate of the upward flow (S1) rising in the vicinity of the side wall (21) is 2843 m ³ / hour, and the liquid (A) can be sufficiently mixed in the tank body (2). Moreover, the maximum value of the flow velocity of the horizontal flow (S2) on the lower surface (3a) of the floating roof is 0.059 m / sec, and there is no fear that the floating roof (3) moves carelessly.

Example 3
The simulation was performed under the same conditions as in Example 2 except that the flow rate of the liquid (A) from the injection nozzle (4) was 8.6 m / sec. As a result, the flow rate of the rising flow (S1) rising in the vicinity of the side wall (21) is 2574 m ³ / hour, and the liquid (A) can be sufficiently mixed in the tank body (2). Moreover, the maximum value of the flow velocity of the horizontal flow (S2) on the lower surface (3a) of the floating roof is 0.020 m / sec, and the floating roof (3) does not move inadvertently.

Comparative Example 1
The simulation was performed under the same conditions as in Example 1 except that the number of injection nozzles (4) was one, one was provided on one side wall (21 '), and the flow rate was 14.6 m / sec. As a result, as shown in FIG. 4B, an upward flow rising in the vicinity of one side wall (21) is formed, and this upward flow flows along the floating roof lower surface (3a) to the opposite side wall (21 '). As a result, a downward flow descending along the opposite side wall (21 ′) was formed. The flow rate of the upflow is 4664 m ³ / hour, and the liquid (A) can be sufficiently mixed in the tank body (2), but the horizontal flow (S2) on the lower surface (3a) of the floating roof is shown in Fig. 4 (b). As shown, it is one direction from one side wall (21) to the opposite side wall (21 ′), and the maximum value of the flow velocity is 0.62 m / sec. The floating flow (S2) There is a risk that 3) will collide with the side wall (21 ').

It is a longitudinal section showing typically the floating roof type storage tank of the present invention. It is a cross-sectional view which shows typically the floating roof type storage tank of this invention, and is a figure which shows the horizontal flow in the vicinity of the lower surface of a floating roof. It is a cross-sectional view which shows typically the floating roof type storage tank of this invention, and is a figure which shows the bottom face flow in the vicinity of a bottom face. It is a longitudinal cross-sectional view which shows typically the conventional storage tank (a) and the storage tank (b) which is not provided with the floating roof.

Explanation of symbols

1: Floating roof storage tank 1 ': Storage tank without floating roof 2: Tank body 22: Bottom surface 21, 21': Side wall
d: Inner diameter h0: Height 3: Floating roof 3a: Lower surface 30: Center of gravity 4: Injection nozzle L: Vertical axis A: Liquid S1: Upflow S2: Horizontal flow
A0: Liquid S3: Downflow S4: Bottom flow
h: Liquid depth

Claims (2)

A vertical cylindrical tank body (2),
A floating roof (3) floated on the liquid level of the liquid (A) stored in the tank body,
The liquid (A) forms an upward flow (S1) rising from the bottom surface (22) along the side wall (21) along the entire circumference of the side wall (21) of the tank body,
The upward flow (S1) becomes a horizontal flow (S2) from the side wall (21) toward the center of gravity axis (L) of the floating roof (3) along the lower surface (3a) of the floating roof (3),
The floating roof is configured so that the horizontal flow (S2) merges in the vicinity of the gravity center axis (L) to form a downward flow (S3) descending along the gravity center axis (L) Storage tank (1). In the vicinity of the center of gravity axis (L) of the bottom surface (22) comprises a spray nozzle (4),
The liquid (A) is sprayed from the spray nozzle (4) toward the side wall (21) to form a bottom surface flow (S4) toward the side wall (21) along the bottom surface (22),
The floating roof storage tank (1) according to claim 1, wherein the bottom flow (S4) is configured to be the upward flow (S1).

Images