JP3965012B2 - Hot water bath vaporizer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a heat source fluid vaporizer that vaporizes a low temperature gas such as liquefied natural gas (hereinafter referred to as LNG) using a heat source fluid such as hot water.
[0002]
[Prior art]
As a means for continuously vaporizing a low temperature liquid such as LNG in a small-scale LNG base, a hot water bath type vaporizer using a heat source fluid such as hot water supplied and discharged into the hot water bath is known.
[0003]
An example of a hot water bath type vaporizer is shown in FIG.4 and FIG.5. 4 and 5 show an LNG vaporizer, and this vaporizer includes a hot water bath 51 and a heat transfer tube bundle 53. The hot water bath 51 includes a square shell 54 whose both ends are closed, and a weir plate 55 that partitions the inside of the square shell 54. Hot water 70 is supplied into the hot water bath 51 through a hot water inlet 56 on the side surface of the square shell 54 and a hot water dispersion pipe 57. The supplied hot water 70 overflows from the weir 55, accumulates in the downcomer 58, and is sent from the hot water outlet 59 to the next process of the boiler system. Further, since the square shell 54 has a square structure, it is extremely weak in strength and is reinforced by a large number of reinforcing members 60. Furthermore, the outer surface of the hot water bath 51 is covered with a heat insulating material 61 in order to prevent heat dissipation. The heat transfer tube bundle 53 is provided in the square shell 54, and is formed by arranging a large number of bent multi-pass heat transfer tubes 52 having a 180 ° return bend. Each heat transfer tube 52 is connected to an inlet header 62 and an outlet header 63 in the square shell 54.
[0004]
In such a vaporizer, the hot water 70 is dispersed from the hot water inlet 56 by the hot water dispersion pipe 57 and is uniformly supplied into the hot water bath 51. On the other hand, LNG to be vaporized is supplied from the inlet 64 and distributed to the heat transfer tubes 52 by the inlet header 62. By heat exchange between the LNG in each heat transfer tube 52 and the hot water 70 in the hot water bath 51, the LNG is vaporized in each heat transfer tube 52 by receiving the heat and becomes natural gas (hereinafter referred to as NG). . The NG receives heat from the hot water 70 and is heated in each heat transfer tube 52, gathers at the outlet header 63, and is sent from the outlet 65 to the next process. The supplied hot water 70 is cooled by heat exchange with LNG, overflows from the weir plate 55, accumulates in the downcomer 58, and is sent from the hot water outlet 59 to the next process of the boiler system.
Therefore, according to this hot water bath type vaporizer, LNG can be continuously vaporized by repeatedly supplying and discharging hot water 70.
[0005]
[Problems to be solved by the invention]
As shown in FIGS. 4 and 5, the conventional hot water bath type vaporizer has a square structure of the square shell 54, and each heat transfer tube 52 has a multipath having a 180 ° return bend, and a large number of these are arranged in an array. Therefore, it is necessary to make the hot water bus 51 into a large bus size. Since the square shell 54 has a square structure, it is weak in strength and requires many reinforcing members 60. From the above, the hot water bath type vaporizer becomes larger, and the installation area and the product weight on a small base become larger. When the hot water bath 51 is a large bath size, the supply amount of the hot water 70 is increased, the full water weight is large, and the basic weight is also large.
In addition, since the installation of the hot water bath 51 at the base is performed by installing the reinforcing member 60, the construction of the heat insulating material 61 requires the construction in the production factory because the bottom of the square shell 54 cannot be obtained after the field installation. It was.
[0006]
In view of such circumstances, an object of the present invention is to provide a hot water bath type vaporizer that can be reduced in weight and size and is inexpensive.
[0007]
[Means for Solving the Problems]
As a means for solving the above problems, the present invention provides a heat transfer tube bundle that exchanges heat with hot water to evaporate the liquefied gas in the shell body forming the hot water bath, and this heat transfer tube bundle is provided at the end. In a hot water bath type vaporizer formed by arranging a plurality of multi-pass heat transfer tubes having a plurality of 180 ° return bends, the shell body is formed in a horizontal cylindrical shape, and the heat transfer tube bundle is viewed from the axial direction of the cylinder. The return bend is arranged so as to include a slant so that the heat transfer tube can be effectively arranged in a cylindrical cross section.
According to this configuration, by making the shell body a horizontal cylindrical shape, a reinforcing member such as a square shell is not necessary, and the product weight can be reduced. The heat transfer tubes of the heat transfer tube bundle can be effectively arranged within the cylindrical cross section of the shell body by arranging the return bend to include an oblique line.
Moreover, at the installation site, it is installed only by supporting the circumference of the shell body, and can be applied to the circumference of the shell body even after the heat insulation work is installed.
[0008]
The rows of multi-pass heat transfer tubes are arranged one above the other by return bends to form the heat transfer tube bundle, and a pair of rectifying plates are provided on both side surfaces of the horizontal cylinder.
By providing a pair of rectifying plates on both side surfaces of the horizontal cylinder, a space where hot water bypasses between the heat transfer tube bundle and the inner periphery of the shell body can be eliminated.
Furthermore, it is preferable that at least one of the pair of rectifying plates also serves as the warm water dam plate. Thereby, the flow distribution of the warm water with respect to the heat exchanger tube of a heat exchanger tube bundle can be improved.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a preferred embodiment of the present invention will be described with reference to FIGS. 1 is a cross-sectional front view showing a hot water bath type vaporizer according to an embodiment of the present invention, FIG. 2 is a cross-sectional view taken along line AA of FIG. 1, and FIG. 3 is a transmission diagram in FIGS. It is an expansion perspective view which shows the arrangement | positioning aspect of the heat exchanger tube of a heat tube bundle.
[0010]
The hot water bath type vaporizer shown in FIGS. 1 and 2 is suitable for a small base, and this vaporizer is provided in the shell main body 2 forming the hot water bath 1 and in the shell main body 2. The heat transfer tube bundle 3 and a pair of rectifying plates 15 and 16 are provided.
[0011]
The shell body 2 is formed in a horizontal cylindrical shape, and the hot water bath 1 is formed by closing both ends with the cover plates 4 and 5. Since the shell body 2 is a horizontal cylindrical type, it is strong in strength and does not require a reinforcing member. In the shell main body 2, an inlet bedder 6, an outlet header 7, and a hot water dispersion pipe 8 are provided. The inlet header 6 and the outlet header 7 are disposed above and below the cylindrical cross section on the lid plate 4 side, and the hot water dispersion pipe 8 is disposed below the cylindrical cross section. Further, a hot water inlet 9 and a hot water outlet 13 are provided on the side surface of the shell body 2, and two manholes 10 are provided on the upper surface of the shell body 2. The hot water 25 is supplied to the hot water inlet 9 and is uniformly supplied into the hot water bath 1 by the hot water dispersion pipe 8.
[0012]
The heat transfer tube bundle 3 evaporates LNG by exchanging heat with the hot water 25. As clearly shown in FIG. 2, the heat transfer tube bundle 3 is formed by arranging a large number of heat transfer tubes 11, and each of the heat transfer tubes 11 includes It is arranged above and below between the headers 6 and 7. Each heat transfer tube 11 is bent with a 180 ° return bend 12, extends horizontally into the shell body 2, and is passed many times. In addition, the start end and the end of each heat transfer tube 11 are connected in each header 6, 7. As clearly shown in FIGS. 2 and 3, when viewed from the axial direction of the inner periphery of the shell body 2, each heat transfer tube 11 has a plurality of return bends 12 arranged in parallel or obliquely with respect to the horizontal direction. Thereby, it arrange | positions in the zigzag shape which spreads toward the inner periphery of the shell main body 2. FIG. The return bends 12 of the heat transfer tubes 11 are selected and combined with the parallel and oblique arrangements described above, so that gaps are formed between the rows of the heat transfer tubes 11 and spread around the inner periphery of the shell body 2. In the heat transfer tube bundle 3, the return bends 12 of the heat transfer tubes 11 are arranged in parallel or obliquely, so that the heat transfer tubes 11 can be effectively arranged in the cylindrical cross section of the shell body 2.
Specifically, as clearly shown in FIG. 2, the return bends 12A and 12B closest to the headers 6 and 7 in the heat transfer tubes 11A and 11B on both sides of the heat transfer tube bundle 3 are connected to the headers. 6, 7 or parallel to the horizontal direction. The other return bends 12 between the return bends 12A and 12B are arranged obliquely with respect to the horizontal direction as described above. Further, in the other heat transfer tubes 11 between the heat transfer tubes 11A and 11B, the return bends 12 are arranged in parallel or obliquely with respect to the horizontal direction as described above so that a gap is formed between each row of the heat transfer tubes 11. Place them in a zigzag pattern. Thus, in the heat transfer tube bundle 3, the heat transfer tubes 11 are arranged to be long in the horizontal direction in a state where they are crushed from the side orthogonal to the horizontal direction, and are effectively arranged in the cylindrical cross section of the shell body 2. it can. The horizontal direction is a direction in which the headers 6 and 7 are extended.
[0013]
The pair of rectifying plates 15 and 16 are provided on both side surfaces of the horizontal cylinder in the shell body 2. As clearly shown in FIG. 2, each of the rectifying plates 15 and 16 is disposed close to both sides of the heat transfer tube bundle 3, so that the hot water 25 is between the heat transfer tube bundle 3 and the inner periphery of the shell body 2. Can eliminate the space to bypass. The rectifying plate 16 is inclined on the outlet header 7 side, and is also used as a dam plate for blocking the supplied hot water 25. The supplied hot water 25 overflows from the current plate 16, accumulates in the downcomer 18, and is sent from the hot water outlet 13 to the next process of the boiler system.
[0014]
In the warm water bath type vaporizer, the warm water 25 is dispersed from the warm water inlet 9 by the warm water dispersion pipe 8 and is uniformly supplied into the warm water bath 1. On the other hand, the LNG to be vaporized is supplied from the inlet 17 and distributed to the heat transfer tubes 11 of the heat transfer tube bundle 3 by the inlet header 6. By the heat exchange between the LNG in each heat transfer tube 11 and the hot water 25, the LNG evaporates in each heat transfer tube 11 by receiving the heat and becomes NG. The NG receives heat from the hot water 25 and is heated in each heat transfer tube 11, gathers at the outlet header 7, and is sent from the outlet 18 to the next process.
[0015]
In this hot water bath type vaporizer, since the shell main body 2 is formed in a horizontal cylindrical shape, a reinforcing member such as a square shell is not necessary, the product weight can be reduced, and the cost can be reduced. Further, each heat transfer tube 11 of the heat transfer tube bundle 3 can be effectively arranged in the cylindrical cross section of the shell body 2 by arranging a plurality of return bends 12 in parallel or obliquely with respect to the headers 6 and 7 or the horizontal direction. The vaporizer including the shell body 2 and the like can be downsized. Further, by reducing the size of the vaporizer, the installation area can be reduced, the full water weight can be reduced, and the basic weight can be reduced. In addition, at the installation site, as clearly shown in FIG. 1, the shell body 2 can be installed just by supporting the circumference of the shell body 2 with the saddle 19, and the construction of the heat insulating material 20 is performed on the circumference of the shell body 2 even after installation. This will improve the site workability and maintainability.
[0016]
By providing the pair of rectifying plates 15 and 16, a space where the hot water 25 bypasses between the heat transfer tube bundle 3 and the inner periphery of the shell body 2 can be eliminated, and circulation of the hot water 25 to the heat transfer tube bundle 3 can be eliminated. As a result, the heat exchange between the hot water 25 and the LNG can be enhanced, and the vaporization performance of the LNG can be improved. . Further, by using the rectifying plate 16 also as the barrier plate, the flow distribution of the warm 25 water with respect to the heat transfer tube 11 of the heat transfer tube bundle 3 is improved, and the vaporization performance of LNG can be improved.
[0017]
Further, by adopting a structure in which the heat transfer tube bundle 3 can be extracted from the shell main body 2, the inspection and maintenance of the heat transfer tube bundle 3 performed by removing the lid member 4 from the shell main body 2 can be easily performed. Further, simple inspection and maintenance can be performed by an operator entering the shell body 2 from the manhole 10 without extracting the heat transfer tube bundle 3.
[0018]
In addition, embodiment of this invention is not restricted to illustration, For example, it can take the following forms.
(1) The arrangement of the return bends 12 of the heat transfer tubes 11 can be arranged in a zigzag shape by selecting and combining the orthogonal bends in addition to the parallel and oblique to the headers 6 and 7.
(2) The vaporization of liquefied natural gas as the liquefied gas has been described. However, the present invention is not limited to this. For example, vaporized liquefied ethylene, LO ₂ (liquefied oxygen), LN ₂ (liquefied nitrogen), etc. It can also be applied to.
(3) Each header 6 and 7 is not restricted to what is arrange | positioned at the cover plate 4 side which is one end of the shell main body 2, It can also each arrange | position at both sides.
(4) The headers 6 and 7 can be formed by pipes, and can also be formed by partitioning a cylindrical body closed at both ends with a partition plate.
[0019]
【The invention's effect】
As described above, according to the present invention, since the shell main body is formed in a horizontal cylindrical shape, a reinforcing member such as a square shell is not necessary, the product weight can be reduced, and the cost can be reduced. In addition, each heat transfer tube of the heat transfer tube bundle can be effectively arranged in the cylindrical cross section of the shell body by arranging the return bend including the slant, and the vaporizer including the shell body can be downsized.
Thereby, the installation area of the hot water bath type vaporizer can be reduced, the full water weight can be reduced, and the basic weight can also be reduced.
Furthermore, it can be installed simply by supporting the circumference of the shell body, and the insulation work can be performed on the shell body even after installation, improving the local workability and maintainability.
[Brief description of the drawings]
FIG. 1 is a cross-sectional front view showing a hot water bath type vaporizer according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line AA of FIG.
FIG. 3 is an enlarged perspective view showing an arrangement mode of heat transfer tubes of the heat transfer tube bundle in FIGS. 1 and 2;
FIG. 4 is a cross-sectional front view showing a conventional hot water bath type vaporizer.
5 is a cross-sectional view taken along the line BB in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Hot water bath 2 Shell main body 3 Heat transfer tube bundle 11 Heat transfer tube 12 Return bend 15 Current plate 16 Current plate

Claims (2)

A heat transfer tube bundle that exchanges heat with hot water to evaporate the liquefied gas is provided in the shell body forming the hot water bath, and this heat transfer tube bundle is provided with a multi-pass heat transfer tube having a plurality of 180 ° return bends at the ends. In the hot water bath type vaporizer formed by arranging multiple rows,
The shell body has a horizontal cylindrical shape, and when viewed from the axial direction of the cylinder, the return bend is disposed so as to include an angle so that the heat transfer tubes of the heat transfer tube bundle can be effectively disposed in a cylindrical cross section.
The hot water bath carburetor is characterized in that rows of multi-pass heat transfer tubes are vertically arranged by the return bend to form the heat transfer tube bundle, and a pair of rectifying plates are provided on both side surfaces of the horizontal cylinder. . The hot water bath type vaporizer according to claim 1 , wherein at least one of the pair of rectifying plates is also used as the hot water dam plate.

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