KR102601142B1 - vaporizer - Google Patents

Abstract

The vaporization device (ORV(1)) includes a heat exchange panel (2) and a trough (3) disposed adjacent to the heat exchange panel (2) and allowing the heat medium to flow to the outer surface of the heat exchange panel. The trough extends in the first direction, and a slit 52 extending in the first direction is formed on the side wall of the trough facing the heat exchange panel at an intermediate position in the height direction. The heat medium stored in the trough flows to the outer surface of the heat exchange panel through the slit.

Description

vaporizer

The technology disclosed herein relates to vaporization devices.

Patent Document 1 describes a device for vaporizing liquefied gas to be mounted on a ship or the like. This vaporization device is a so-called open rack type vaporization device. The open rack type vaporizer includes a heat exchange panel and a trough. A heat exchange panel is constructed by arranging a plurality of heat transfer tubes in a first direction. The heat exchange panel vaporizes the liquefied gas inside each heat pipe. The heat exchange panels are arranged in a second direction orthogonal to the first direction. The trough extends in the first direction between adjacent heat exchange panels. The trough supplies heat medium to the outer surface of the heat exchange panel. The heat medium in the trough overflows from the opening when the water surface becomes higher than the edge of the opening at the upper end of the trough.

The vaporization device described in Patent Document 1 is installed in a place that fluctuates. The trough has a partition plate in the center that is higher than the edge of the opening. With this configuration, even when the trough is tilted in the second direction, the heat medium can overflow from the opening and supply the heat medium to the heat exchange panel.

Patent Document 1: Japanese Patent No. 6053389

In the vaporization device described in Patent Document 1, the interior of the trough is divided into a plurality of sections in the first direction so that heat medium can be supplied to the entire heat exchange panel even when it is tilted in the first direction, that is, in the longitudinal direction of the trough.

However, if the vaporization device described in Patent Document 1 is tilted greatly in the first direction, there is a risk that the heat medium will have difficulty overflowing or will not overflow at the end of the trough in the first direction.

The technology disclosed here makes it possible to supply heat medium to the heat exchange panel from the entire trough even when the vaporizer is tilted in the longitudinal direction.

The technology disclosed herein relates to vaporization devices.

This vaporization device is comprised of a plurality of heat transfer tubes arranged in a first direction, a heat exchange panel for vaporizing the liquefied gas flowing inside each heat transfer tube, and a second heat exchange panel orthogonal to the first direction. and a trough disposed adjacent to each other in one direction and allowing a heat medium to flow to an outer surface of the heat exchange panel, wherein the trough extends in the first direction, and a side wall of the trough facing the heat exchange panel is provided with A slit extending in the first direction is formed at an intermediate position in the height direction, and the heat medium stored in the trough flows to the outer surface of the heat exchange panel through the slit.

According to the vaporization device of this configuration, a slit extending in the first direction is formed at an intermediate position in the height direction of the side wall of the trough. If the water surface in the trough is at a higher position than the slit, the heat medium stored in the trough flows to the outer surface of the heat exchange panel through the slit. The amount of heat medium supplied to the heat exchange panel corresponds to the vertical width of the slit. The “middle position” is an arbitrary position between the upper and lower ends of the side wall, and the slit can be formed at an appropriate height so that the heat medium can be stably supplied to the heat exchange panel.

When the vaporizer is tilted in the first direction, one end of the trough in the first direction moves upward and the other end moves downward. At the end of the trough that moves upward, the height difference between the upper end of the side wall of the trough and the water surface becomes smaller. However, this trough is not configured to overflow the heat medium. This trough supplies heat medium to the heat exchange panel through a slit formed in the middle of the side wall in the height direction. When the vaporizer is tilted in the first direction and the water surface in the trough is at a higher position than the slit, the heat medium flows through the slit to the outer surface of the heat exchange panel. At this time, the supply amount of the heat medium is an amount corresponding to the vertical width of the slit. Accordingly, the vaporization device of the above configuration can supply the heat medium evenly or substantially evenly throughout the first direction of the heat exchange panel, even when tilted in the first direction.

The trough has a supply port for supplying the heat medium into the trough, and a baffle plate disposed between the supply port and the side wall, and the heat medium passes through a position below the slit so as to bypass the baffle plate. It may flow from the supply port to the slit.

By doing this, the heat medium supplied into the trough from the supply port passes through the baffle plate at a position below the slit and flows into the space between the side wall and the baffle plate. While the heat medium bypasses the baffle plate, the heat medium spreads and flows in the first direction. The heat medium is distributed evenly or approximately equally throughout the first direction within the trough. Whether the vaporizer is horizontal or tilted in the first direction, the trough can allow the heat medium to flow evenly or approximately evenly throughout the entire heat exchange panel.

The baffle plate is disposed at intervals in the second direction with respect to the side wall and extends in the first direction, and the trough defines a space between the side wall and the baffle plate in the first direction. You may have a guide plate that divides into multiple sections.

Here, the guide plate may completely divide two spaces adjacent to each other with the guide plate in between, or may divide the two spaces so that parts of them are connected to each other without completely dividing the two spaces.

The heat medium that passes through a position below the slit and flows into the space between the side wall and the baffle plate is distributed equally or approximately equally to each of the plurality of spaces partitioned by the guide plate. The trough can supply heat medium to the heat exchange panel evenly or approximately equally throughout the first direction.

Additionally, when the vaporizer is tilted in the first direction, the guide plate prevents the heat medium from flowing in the first direction within the trough. Even when the vaporizer is tilted with respect to the first direction, the trough can cause the heat medium to flow evenly or approximately evenly throughout the first direction of the heat exchange panel.

The trough may have a partition plate that divides the space within the trough into multiple parts in the first direction.

Here, the partition plate completely divides two adjacent spaces with the partition plate in between, thereby preventing the heat medium from flowing in the first direction between the space with the partition plate in between. do. Additionally, the partition plate may divide the two spaces so that parts of them are connected to each other, rather than completely dividing the two spaces.

The trough is long in the first direction. When the vaporizer is tilted with respect to the first direction, the partition plate blocks or suppresses the heat medium from flowing in the first direction within the trough. The heat medium is suppressed from being concentrated in one direction in the first direction within the trough. A plurality of troughs divided by a partition plate can supply the heat medium evenly or approximately equally throughout the entire first direction of the heat exchange panel.

The number of the guide plates may be greater than that of the partition plates.

That is, the partition plate may divide the inside of the trough into a plurality of spaces, and the guide plate may further divide each of the plurality of spaces into a plurality of spaces. By forming both a guide plate and a partition plate in the trough, even when the vaporizer is tilted with respect to the first direction, the heat medium is supplied evenly or substantially evenly throughout the first direction of the heat exchange panel.

The trough may have a trough body and a limiting plate that is detachably attached to the trough body and constitutes a part of the side wall, and the slit may be formed between the trough body and the limiting plate.

When the heat medium is seawater, trash or shells in the seawater may block part of the slit. By separating the limiting plate from the trough main body, trash and the like can be easily removed. Maintenance of the vaporizer becomes easier.

The vertical width of the slit may be adjusted by changing the mounting position of the limiting plate.

By changing the size of the upper and lower widths of the slits, the amount of heat medium supplied from the trough to the heat exchange panel can be adjusted. Additionally, seawater as a heat medium sometimes contains a lot of trash. If the top and bottom width of the slit is widened according to the usage environment of the vaporizer, clogging of the slit with waste, etc. is suppressed.

The vaporization device may be installed on a floating body.

As mentioned above, this vaporization device can supply heat medium from the entire trough to the heat exchange panel even when tilted in the longitudinal direction, so it is a vaporization device installed on floating bodies in seawater (including ships and moored floats, etc.). It is appropriate.

As explained above, the vaporization device can cause the heat medium to flow from the entire trough to the heat exchange panel even when the vaporization device is tilted.

1 is a perspective view schematically illustrating the overall configuration of the vaporization device.
Figure 2 is a perspective view illustrating the configuration of a trough.
Figure 3 is a top view of the trough.
Figure 4 is a side view of the trough.
Figure 5 is a cross-sectional view of a partial fracture of the trough.
Figure 6 is a diagram illustrating the mounting structure of the limiting plate.
Figure 7 is a side view illustrating a state in which the vaporization device is tilted in the first direction.
Figure 8 is a cross-sectional view illustrating a state in which the vaporization device is tilted in the second direction.

Hereinafter, embodiments of the vaporization device will be described with reference to the drawings. The vaporization device described here is an example. Figure 1 schematically shows the overall configuration of the vaporization device. The vaporization device is a so-called open rack vaporizer (ORV) (1). ORV (1) is installed on a floating body. ORV 1 is mounted on a liquefied gas carrier, for example. ORV 1 converts the transported liquefied gas into gaseous gas by heat-exchanging it with seawater as a heat medium. ORV (1) may also be installed in a Floating Storage and Regasification Unit (FSRU) or Floating Production, Storage and Offloading (FPSO).

ORV (1) is provided with a plurality of heat exchange panels (2). In the drawing example, there are five heat exchange panels 2. Additionally, the number of heat exchange panels 2 may be an appropriate number. Although detailed illustration is omitted, each heat exchange panel 2 is configured by arranging a plurality of heat transfer tubes in the first direction and joining adjacent heat transfer tubes to each other. Five heat exchange panels 2 are arranged in a second direction orthogonal to the first direction. Here, the first direction corresponds to the direction connecting the bow and stern of the ship carrying ORV 1. The second direction corresponds to the direction connecting the port and starboard sides of the ship.

A lower header tank 21 is disposed below each heat exchange panel 2. One lower header tank (21) is arranged per heat exchange panel (2). The lower header tank 21 extends in the first direction. The lower end of each heat pipe is connected to the lower header tank (21). The lower header tank 21 distributes the liquefied gas to each heat pipe. The ends of the lower header tanks 21 arranged in the second direction are connected to the inlet manifold 22 extending in the second direction. The inlet manifold 22 distributes the liquefied gas to each lower header tank 21.

The liquefied gas is supplied to each heat transfer pipe through the inlet manifold 22 and the lower header tank 21, and is vaporized while flowing through the heat transfer pipe from bottom to top.

An upper header tank 23 is disposed above each heat exchange panel 2. One upper header tank (23) is disposed per heat exchange panel (2). The upper header tank 23 extends in the first direction. The upper end of each heat pipe is connected to the upper header tank (23). The upper header tank 23 collects gas from each heat transfer tube. The ends of the upper header tanks 23 arranged in the second direction are connected to the outlet manifold 24 extending in the second direction. The outlet manifold 24 collects gas from each upper header tank 23 and sends it out.

Additionally, the liquefied gas may be supplied to each heat transfer tube through the upper header tank 23 and vaporized while flowing from top to bottom within the heat transfer tube.

For each heat exchange panel 2, troughs 3 are disposed on both sides in the second direction. The trough 3 stores seawater and causes the stored seawater to flow to the outer surface of the heat exchange panel 2. The trough 3 extends in a first direction near the top of the heat exchange panel 2.

Figure 2 is a perspective view illustrating the overall configuration of the trough 3. Figure 3 is a top view of the trough 3, and Figure 4 is a side view of the trough 3. Figure 5 is a broken cross-sectional view of the trough 3. 5 shows only two heat exchange panels 2 and shows three troughs 3 corresponding to the two heat exchange panels 2. The trough 3 at the left end in FIG. 5 is the trough 3 disposed at the leftmost end in FIG. 1 and corresponds to the trough 3 at the end of the ORV 1, and is the trough 3 at the right end in FIG. ) is the trough 3 located at the rightmost end in FIG. 1 and corresponds to the trough 3 at the end of ORV 1. The trough 3 disposed between the adjacent heat exchange panels 2 and the heat exchange panel 2 has a cross-sectional shape as if two troughs 3 disposed at the ends are facing each other back to back.

The trough 3 has a trough main body 4 and a limiting plate 5 mounted on the trough main body 4. The trough body 4 has a bottom wall 41, two side walls 42, and two end walls 43. The trough body 4 is opened upward.

The bottom wall 41 extends in the first direction. The side wall 42 continues to the edge of the bottom wall 41 in the second direction. Each side wall 42 extends in the first direction. The two side walls 42 are arranged to face each other in the second direction. Each side wall 42 faces the heat exchange panel 2. The end wall 43 continues to the end of the bottom wall 41 in the first direction. The end wall 43 connects the two opposing side walls 42 to each other. The height of the end wall 43 is higher than the height of the side wall 42.

An edge portion 421 is formed at the upper end of the side wall 42. The edge portion 421 is formed by bending the upper part of the side wall 42 outward in the second direction. The edge portion 421 slopes inclined downward. The edge portion 421 is continuous throughout the side wall 42 extending in the first direction. The seawater in the trough (3) flows along the edge portion (421) toward the heat exchange panel (2).

The limiting plate 5 is located above the side wall 42 and thus constitutes a part of the side of the trough 3. The limiting plate 5 extends in the first direction. Both ends of the limiting plate 5 in the first direction are bent. Both ends of the limiting plate 5 are respectively fixed to the end walls 43. The limiting plate (5) is mounted to the end wall (43) with bolts (51). The limiting plate (5) is detachable from the trough body (4).

A gap is formed between the limiting plate 5 and the side wall 42. As a result, a slit 52 extending in the first direction is formed on the side wall of the trough 3 at an intermediate position in the height direction. More specifically, the slit 52 is located above the central position of the side wall of the trough 3 with the entire height from the upper end of the limiting plate 5 to the lower end of the side wall 42. In addition, the height position of the slit 52 is not limited to the drawing example, and can be set to an appropriate position. Additionally, the slits 52 are continuous from end to end of the trough 3 in the first direction.

As shown in Fig. 6, the bolt hole 53 for mounting the limiting plate 5 is long in the vertical direction. The mounting position of the limiting plate 5 with respect to the trough main body 4 can be changed in the vertical direction. As shown in the left drawing of FIG. 6, when the limiting plate 5 is mounted below, the vertical width W1 of the slit 52 becomes narrow, and as shown in the right drawing, when the limiting plate 5 is mounted on top. The upper and lower width W2 of the slit 52 becomes wider.

Within the trough 3, a partition wall 61 is disposed. The partition 61 extends in the first direction at a central position in the second direction. The partition wall 61 is in contact with the bottom wall 41. The height of the partition wall 61 is higher than the height of the end wall 43. The partition 61 divides the inside of the trough 3 into two in the second direction. As will be described in detail later, the partition 61 makes it possible to stably supply seawater to the heat exchange panels 2 on both sides of the trough 3 when the vaporizer 1 is tilted in the second direction.

And, as shown in FIG. 5, in the trough 3 disposed at the end in the second direction, that is, the trough 3 at the left end and the trough 3 at the right end in FIG. 5, one side wall 42 This is configured to be higher than the height of the end wall 43. The side wall 42, which is higher than the height of the end wall 43, performs the same function as the partition wall 61.

Within the trough 3, a plurality of partition plates 62 are disposed. The plurality of partition plates 62 are arranged at equal intervals in the first direction in each of the two spaces within the trough 3 divided by the partition wall 61. Each partition plate 62 is in contact with the bottom wall 41, the side wall 42, and the partition wall 61, respectively. The upper end of each partition plate 62 is located at the same or approximately the same height as the upper end of the end wall 43. In the example drawing, in each of the two spaces in the trough 3 divided by the partition 61, four partition plates 62 divide the inside of the trough 3 into five spaces in the first direction. . Additionally, the number of divisions in the first direction by the partition plate 62 is not limited to five. The inside of the trough 3 can be divided into an appropriate number in the first direction. Additionally, the inside of the trough 3 does not need to be divided in the first direction. The partition plate 62 can also be omitted.

The trough 3 has a supply port 71 for supplying seawater into the trough 3. The supply port 71 is individually formed in each of a total of 10 spaces divided by the partition wall 61 and the partition plate 62. More specifically, the supply port 71 is formed in the distribution pipe 72 disposed within the trough 3. The distribution pipe 72 is composed of a pipe with both ends closed. The distribution pipe 72 is arranged to extend in the first direction in each of the two spaces divided by the partition 61. The distribution pipe 72 penetrates the partition plate 62. The supply port 71 formed at a predetermined position of the distribution pipe 72 is located within each space divided in the first direction. The supply port 71 is formed at the lower part of the distribution pipe 72 and opens downward.

Although detailed illustration is omitted, a supply pipe 73 is connected to each distribution pipe 72 (see also FIG. 1). The seawater supplied to each distribution pipe 72 through the supply pipe 73 is jetted into the trough 3 through each supply port 71.

A baffle plate 81 is disposed between the supply port 71 and the side wall 42. The baffle plate 81 restricts the flow of seawater in the trough 3. Specifically, the baffle plate 81 is arranged in parallel with the side wall 42 at a predetermined interval in the second direction with respect to the side wall 42 . The lower end of the baffle plate 81 is spaced apart from the bottom wall 41 of the trough 3. The lower end of the baffle plate 81 is located below the slit 52. As indicated by the arrow in FIG. 5, seawater flows to bypass the baffle plate 81. More specifically, seawater passes through a position below the slit 52 and flows from the supply port 71 into the space between the side wall 42 and the baffle plate 81.

A guide plate 82 is disposed in the space between the side wall 42 and the baffle plate 81. The guide plate 82 divides the space between the side wall 42 and the baffle plate 81 into a plurality of spaces in the first direction. In the drawing example, in each space divided by the partition plate 62, four guide plates 82 are arranged at equal intervals in the first direction. The space is divided into five parts by the guide plate 82. The guide plates 82 are more numerous than the partition plates 62.

Each guide plate 82 is fixed to the baffle plate 81 and is fixed to the limiting plate 5. The baffle plate 81 is fixed to the limiting plate 5 via a guide plate 82.

In the drawing example, the lower end of the guide plate 82 is set at the same position as the lower end of the baffle plate 81. The guide plate 82 does not partition two adjacent spaces with the guide plate 82 in between near the bottom wall 41 of the trough 3. Although not shown, the lower end of the guide plate 82 may contact the bottom wall 41 of the trough 3.

As described above, seawater passes through a position below the slit 52 to bypass the baffle plate 81 and flows from the supply port 71 into the space between the side wall 42 and the baffle plate 81. It flows. The guide plate 82 distributes seawater equally or approximately equally to each space defined by the guide plate 82 in the space between the side wall 42 and the baffle plate 81.

The upper end of the guide plate 82 is inclined so as to connect the upper end of the baffle plate 81 and the upper end of the limiting plate 5. Also, unlike the drawing example, the upper end of the guide plate 82 may be formed straight and horizontal.

The limiting plate 5, baffle plate 81, and guide plate 82 are integrated by being fixed to each other. The rigidity of the long limiting plate 5 and baffle plate 81 in the first direction increases.

Additionally, the limiting plate 5 is detachably mounted on the trough main body 4. When the limiting plate 5 is separated from the trough body 4, the limiting plate 5, baffle plate 81, and guide plate 82 can be separated from the trough body 4 (see Figures 4 and 5 (see dotted and dashed lines). As will be described later, seawater stored in the trough 3 flows through the slit 52, but the slit 52 may be blocked by debris or shells contained in the seawater. By separating the limiting plate 5, baffle plate 81, and guide plate 82 from the trough main body 4, the operator can easily remove waste accumulated in the slit 52, etc. The separate configuration of the limiting plate 5, the baffle plate 81, and the guide plate 82 improves the maintenance performance of the trough 3.

The trough 3 of the above-described configuration supplies seawater stored in the trough 3 to the outer surface of the heat exchange panel 2 through the slit 52 formed in the middle of the side wall 42. As illustrated in FIG. 5 , seawater flows toward the outer surface of the heat exchange panel 2 along the edge portion 421. The slits 52 extend with the same width in the first direction. The trough 3 can supply seawater evenly or substantially evenly throughout the first direction of the heat exchange panel 2.

ORV(1) is mounted on the ship in this configuration example, so when the ship shakes in the pitching direction under the influence of wind or waves, ORV(1) tilts in the first direction, and when the ship shakes in the rolling direction, ORV(1) ) is inclined in the second direction. As illustrated in FIG. 7, when the trough 3 is tilted in the first direction as the ORV 1 is tilted in the first direction (see θ in FIG. 7), one end of the trough 3 in the first direction The end of the other side moves upward, and the end of the other side moves downward.

Since the conventional trough allows seawater to overflow from the upper end of the side wall, as the trough 3 tilts in the first direction, the upper end of the side wall moves relatively upward compared to the water surface, and the upper end of the side wall As the difference in elevation with the water surface becomes smaller, seawater either does not overflow or becomes difficult to overflow.

On the other hand, the trough 3 of the above-described configuration supplies seawater to the outer surface of the heat exchange panel 2 through the slit 52 formed in the middle position of the side wall 42. Even if the trough 3 is tilted in the first direction, as illustrated by the two-dot chain line in FIG. 7, if the water surface WL in the trough 3 is at a higher position than the slit 52, the vertical width of the slit 52 An amount of seawater corresponding to can be supplied to the heat exchange panel 2 throughout the first direction. A situation in which seawater is not supplied to a part of the ORV 1 can be avoided, and the ORV 1 can vaporize the liquefied gas satisfactorily.

Here, the ORV 1 mounted on the ship operates, for example, while the ship is at anchor. For a ship at anchor, the swing angle in the pitching direction is relatively small. The angle θ at which the trough 3 is inclined in the first direction is, for example, several degrees. In addition, as described above, the trough 3 is divided into plural parts in the first direction by the partition plate 62. As a result, even when the trough 3 is tilted in the first direction, the water surface in each space divided by the partition plate 62 is prevented from being lower than the slit 52. The trough 3 can cause seawater to flow to the heat exchange panel 2 throughout the first direction.

In addition, since a plurality of guide plates 82 are formed between the side wall 42 and the baffle plate 81, when the trough 3 is tilted in the first direction, the side wall 42 and the baffle plate 81 ), the flow of seawater in the first direction is prevented by the guide plate 82. The trough 3 can supply seawater evenly or approximately evenly throughout the first direction of the heat exchange panel 2.

In addition, the baffle plate 81 restricts the flow of seawater within the trough 3, so that the seawater supplied from the supply port 71 into the trough 3 is distributed equally or approximately in the first direction within the trough 3. It can be distributed evenly. As a result of suppressing the concentration of seawater within the trough 3, whether the trough 3 is horizontal or tilted, seawater flows through the slit 52 in the first direction of the heat exchange panel 2, Flows evenly or approximately evenly.

The guide plate 82 between the side wall 42 and the baffle plate 81 not only prevents the movement of seawater when the trough 3 is tilted in the first direction, but also prevents the movement of seawater by bypassing the baffle plate 81. It also contributes to distributing seawater flowing into the space between the side wall 42 and the baffle plate 81 equally or approximately equally in the first direction.

In addition, a partition plate 62 that divides the long trough 3 in the first direction into a plurality of sections, and a guide plate 82 that further divides the space partitioned by the partition plate 62 into a plurality of sections. ) is placed in the trough 3, so that seawater can be supplied evenly or approximately evenly throughout the first direction of the heat exchange panel 2, regardless of whether the trough 3 is horizontal or inclined in the first direction. You can.

Additionally, by changing the size of the vertical width of the slit 52 by changing the mounting position of the limiting plate 5, the amount of seawater supplied from the trough 3 to the heat exchange panel 2 can be easily adjusted.

Additionally, by widening the vertical width of the slit 52, it is possible to prevent debris contained in seawater from clogging the slit 52. By changing the vertical width of the slit 52 according to the usage environment of the ORV 1, the ORV 1 can be operated stably.

In addition, since the trough 3 is divided into two in the second direction by the tall partition 61, as shown in FIG. 8, when the ORV 1 is tilted in the second direction, the trough 3 Seawater can be supplied to the heat exchange panels (2) on both sides. The rolling angle of a ship at anchor is likely to be larger than the pitching angle, but the trough 3 of the above-described configuration supplies seawater to the heat exchange panels 2 on both sides of the trough 3 even if the ship rolls at a relatively large angle. You can continue.

Although not shown, the trough 3 located at the end in the second direction has a high side wall 42, so that when the ORV 1 is tilted in the second direction, the trough 3 is positioned at the end of the trough 3. Seawater can be supplied to the heat exchange panel (2). The high side wall 42 performs the same function as the partition wall 61.

Additionally, the configuration of the vaporization device 1 is not limited to the configuration of the ORV 1 described above. For example, as a mechanism for supplying seawater to each space in the trough 3 partitioned by the partition wall 61 and/or the partition plate 62, the distribution pipe 72 described above is disposed within the trough 3. It may be of a configuration other than that described above. For example, supply pipes may be individually connected to each space within the trough 3.

Additionally, the number of guide plates 82 is not limited to the configuration example described above. The number of guide plates 82 may be sufficient. Additionally, the guide plate 82 may be omitted.

Additionally, the baffle plate 81 can also be omitted.

The slits 52 do not have to be continuous from end to end of the trough 3 in the first direction. The slit may be divided into a plurality of slits in the first direction.

1: ORV (vaporization device)
2: Heat exchange panel
3: Trough
4: Trough body
42: side wall
5: Limited edition
52: slit
62: partition board
71: Supply port
81: Baffle plate
82: Guide plate

Claims (8)

A heat exchange panel composed of a plurality of heat transfer tubes arranged in a first direction and vaporizing the liquefied gas flowing inside each heat transfer tube;
a trough disposed adjacent to the heat exchange panel in a second direction perpendicular to the first direction and allowing a heat medium to flow to an outer surface of the heat exchange panel;
The trough extends in the first direction, and a slit extending in the first direction is formed on a side wall of the trough facing the heat exchange panel at an intermediate position in the height direction of the trough,
The trough has a supply port for supplying the heat medium into the trough, and a baffle plate disposed between the supply port and the side wall,
The baffle plate is disposed at intervals in the second direction with respect to the side wall and extends in the first direction,
The trough is a guide plate that divides the space between the side wall and the baffle plate into a plurality of sections in the first direction, and the heat medium flows from the supply port to the space between the side wall and the baffle plate, It has a guide plate for distributing to each of a plurality of spaces partitioned by the guide plate,
The heat medium stored in the trough passes a position below the slit so as to bypass the baffle plate, flows from the supply port to the slit, and flows through the slit to the outer surface of the heat exchange panel. According to paragraph 1,
The vaporization device wherein the trough has a partition plate that divides the space within the trough into a plurality of parts in the first direction. According to paragraph 1,
The trough has a partition plate dividing the space within the trough into a plurality of parts in the first direction,
A vaporization device in which the guide plate is greater in number than the partition plate. According to any one of claims 1 to 3,
The trough has a trough body and a limiting plate that is detachably mounted on the trough body and forms a part of the side wall,
The slit is a vaporization device formed between the trough body and the limiting plate. According to paragraph 4,
A vaporizer in which the vertical width of the slit is adjusted by changing the mounting position of the limiting plate. According to any one of claims 1 to 3,
The vaporization device is a vaporization device installed on a floating body. According to paragraph 4,
The vaporization device is a vaporization device installed on a floating body. According to clause 5,
The vaporization device is a vaporization device installed on a floating body.

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