JPH08110181A - Thermal insulation structure of open rack type vaporizer - Google Patents

Abstract

PURPOSE: To provide a thermal insulation structure of an open rack type vaporizer which is capable of being excellently fitted to an upper header of a panel and a finned tube, and securing the sufficient thermal insulation performance, and is inexpensive and easy for maintenance. CONSTITUTION: A part in the vicinity of a connection part of an upper header 1 of a panel to a finned tube 3 is surrounded by a resin foam member provided with an FRP film layer 22 on the outer layer part, and a sealing member consisting of EPFM or melamine resin foam is provided between the FRP film layer 22 and the finned tube 3 at the lower side part of the resin foam member to constitute a thermal insulation cover 2, and the lower end part of the outer layer side of this thermal insulation cover 2 is constituted as a sea water feeding part 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an adiabatic structure of an open rack type vaporizer for vaporizing liquefied natural gas with seawater.

[0002]

2. Description of the Related Art The structure of the main part of an open rack type vaporizer 100 will be described with reference to FIG. The carburetor 100 includes a panel upper header 1, a plurality of finned tubes 3 extending below the panel upper header 1, and a panel lower header 4 provided below the finned tubes 3. There is. Further, in the vicinity of the connecting portion between the panel upper header 1 and the finned tube 3, a seawater supply portion 6 for supplying seawater for heating is provided at an outer portion on the finned tube side. Here, the flow path 1a in the panel upper header is connected to the flow path 4a in the panel lower header by the flow path 3c in the plurality of finned tubes. The seawater for heating supplied from the seawater supply unit 6 flows down on the outer surfaces of the tubes 3a and the fins 3b. The liquefied natural gas flowing down in the finned tube is vaporized in the finned tube by heat exchange with the outer surface of the finned tube and the seawater flowing down the fin. Therefore, natural gas in a gas phase can be obtained in the lower header of the panel. Here, the temperature inside the panel upper header is about −160 ° C.,
The temperature at the inlet of the finned tube is also about -160 ° C. On the other hand, the temperatures of seawater and the external atmosphere are room temperature. In such a situation, the conventional panel upper header 1 and
As shown in FIG. 4, in the vicinity of the connection portion of the finned tube 3 connected to the panel upper header 1, an upper side heat insulating cover 20a made of Bakelite is provided at this portion, and a bakelite arranged at the lower side of the cover. And the lower side heat insulating cover 20b manufactured by the company. And the seawater mentioned above
A structure has been adopted in which water is sprayed onto the lower side heat insulating cover, and then the heat is exchanged by advancing to the finned tubes and the outer surfaces of the fins.

[0003]

However, the above-mentioned prior art has the following drawbacks. (1) Bakelite is used as the heat insulating material, but its heat insulating property is not sufficient. (2) Since Bakelite is a hard material, it is troublesome to machine the details (fin portions) and is not well compatible with the other member. (3) It is expensive, heavy, and has problems such as maintenance. (4) Furthermore, since the heat insulation performance is poor, icing sometimes occurs between the finned tube in contact with seawater and the heat insulation cover. This site is indicated by A in FIG. Therefore, an object of the present invention is to obtain a heat insulating structure of an open rack type carburetor which can be well adapted to the panel upper header and the finned tube to ensure sufficient heat insulating performance, and is inexpensive and easy to maintain.

[0004]

In order to achieve this object, the first characteristic constitution according to the first aspect of the present invention in an adiabatic structure of an open rack type vaporizer comprises a water vapor impermeable membrane layer in an outer layer portion. The resin foam member surrounds the vicinity of the connection between the panel upper header and the finned tube, while the lower end of the resin foam member maintains elasticity at low temperature between the water vapor impermeable membrane layer and the finned tube. The heat insulating cover is configured by including a sealing member made of rubber or a resin member, and the outer layer portion of the resin foam member with respect to the vicinity of the connection portion of the finned tube is configured as the seawater supply portion. A second characteristic structure according to claim 2 is the first characteristic structure, wherein the water vapor impermeable membrane layer is an FRP layer, the resin foam member is urethane foam, and the sealing member is EPDM or melamine. It is in the form. Further, a third characteristic structure according to claim 3 is the first characteristic structure, wherein the heat insulating cover is divided into two parts in an upper part of the panel upper header along an axial direction of the panel upper header. To be there. A fourth characteristic configuration according to claim 4 is that, in the second characteristic configuration, a metal layer is provided as an outer layer of the FRP layer. Further, a fifth characteristic configuration according to claim 5 is that in the second characteristic configuration, the density of the urethane foam is set to 50 kg / m ³ or more and 200 kg / m ³ or less. Furthermore, the sixth characteristic configuration according to claim 6 is the second
In the characteristic constitution of the above, in the density of the urethane foam, a urethane foam layer having a high density is provided on the outer layer side in the radial direction of the panel upper header.
Further, a seventh characteristic structure according to claim 7 is the third characteristic structure, wherein in the divided structure of the heat insulating cover,
The dividing surface formed along the axial direction of the panel upper header is provided with a concave-convex portion that is fitted and connected in a mating member in a state of surrounding the panel upper header. The actions and effects thereof are as follows.

[0005]

In such a heat insulating cover, good heat insulating properties are ensured, and, for example, water in the air is frozen at the heat insulating cover portion, or seawater for heating enters the A portion shown in FIG. Therefore, it is necessary to prevent problems such as freezing. Here, in the case of the configuration of the first characteristic configuration of the present application, each member functions as follows.
Since the resin foam member contains a relatively large amount of air bubbles in the material, it has appropriate heat insulation properties, and at the same time, it fits well with the surface of the panel upper header, which is the abutting member, and the surface near the connection part of the finned tube. , Wrap the member to be heat-insulated well and realize a good heat-insulation state. further,
It has excellent formability, and because it is relatively lightweight, it has good maintainability. The water vapor impermeable membrane layer provided on the outer layer portion of the resin foam member can prevent water from entering the resin foam layer and prevent troubles such as water freezing in the member. Furthermore, as the seal member, a material that maintains elasticity at low temperature is selectively adopted, so that the sealability between the finned tube and the heat insulating cover can be secured, and the finned seawater that often causes problems at this part It is possible to solve problems such as invasion / freezing to the upper end side of the tube (the connection part side), and further corrosion and the like caused thereby.

In the case of the second characteristic constitution of the present application, by adopting urethane foam as the resin foam member, it is possible to obtain good heat insulation performance while being inexpensive and highly practical. On the other hand, FRP as a water vapor impermeable membrane layer
By providing the layer, the permeation of water through the layer is surely prevented, and the high shape-retaining property does not cause a problem even when an impact is applied. EPDM or melamine foam retains sufficient elasticity at low temperatures and exhibits good sealing properties.

In the case of the third characteristic structure of the present application, by disposing the heat insulating cover in a divided structure, disassembly and assembly can be easily carried out, and work such as maintenance can be carried out quickly.

When the fourth characteristic structure of the present application is adopted, the strength of the heat insulating cover can be further ensured.

In the case of the fifth characteristic constitution of the present application, by adopting urethane foam having a density within a predetermined range, it is possible to obtain an appropriate heat insulating cover in terms of both heat insulating performance and strength. Here, if the density is lower than 50 kg / m ³ , the strength is low and cracks may occur at low temperatures. On the other hand, when it is higher than 200 kg / m ³ , the performance at low temperature is insufficient and the weight becomes excessive.

In the case of the sixth characteristic configuration of the present application, it is possible to secure the heat insulating performance on the inner layer side of the heat insulating cover and the shape retention on the outer layer side.

In the case of the seventh characteristic structure of the present application, by providing the uneven portion, positioning between the divided members can be easily performed, and there is a problem such as misalignment or slippage in positioning between the two members. Therefore, it is possible to obtain a good heat insulating cover that can always maintain a good heat insulating state.

[0012]

As a result, it is possible to obtain a heat insulating structure of an open rack type carburetor which can be well adapted to the panel upper header and the finned tube to ensure a sufficient heat insulating performance and which is provided with a heat insulating cover. Furthermore, since it is possible to make the structure inexpensive and easy to maintain, it is possible to easily perform the periodic inspection of the welded portion of the header pipe and the fin tube, which has been a problem in the past.

[0013]

Embodiments of the present application will be described with reference to the drawings. FIG. 1 is a perspective view of a main part of the open rack type carburetor 100, and FIG. 2 is a sectional view near the panel upper header 1.
Further, FIG. 3 shows an exploded perspective view of the heat insulating cover 2. As described above, the vaporizer 100 includes a panel upper header 1, a plurality of finned tubes 3 extending below the panel upper header 1, and a panel lower header provided below the finned tubes 3. 4 is provided. These finned tubes 3
Are connected to each other by fins 3b, and a panel structure is adopted as a whole. Here, the flow path 1a in the panel upper header is connected to the flow path 4a in the panel lower header by the flow path 3c in the plurality of finned tubes. A seawater supply unit 6 for supplying sprinkling seawater for heating is provided at an outer portion on the finned tube side in the vicinity of the connection portion 5 between the panel upper header 1 and the finned tube 3. To take this structure, an open channel trough 9 with a seawater sprinkler 8 is provided on the upper side of each panel 7. Therefore, the seawater supplied by the seawater sprinkling pipe 8 is laterally dispersed in the trough 9 and is also sprinkled and supplied to the seawater supply unit 6 through a predetermined flow path. The seawater for heating supplied from the seawater supply unit 6 flows down on the outer surfaces of the finned tubes 3 and the fins 3b provided between the tubes 3a. The liquefied natural gas flowing down in the flow path 3c of the finned tube 3 is the finned tube 3
The finned tube 3 is vaporized by heat exchange with the seawater flowing down the outer surface. Therefore, natural gas in a vapor phase can be obtained in the panel lower header 4.
Here, the temperature inside the panel upper header 1 is about -160 ° C, and the temperature at the inlet of the finned tube 3 is also about -160 ° C. On the other hand, the temperatures of seawater and the external atmosphere are room temperature.

The above is the configuration of the main part of the open rack type vaporizer 100. Next, the configurations of the panel upper header 1 and the heat insulating cover 2 provided in the vicinity of the connecting portion of the finned tube 3 connected to the panel upper header 1 will be described with reference to FIGS. 2 and 3. This insulation cover 2
Is composed of three parts that are integrally molded. That is, as shown in FIG. 3, the heat insulating cover 2 is composed of a heat insulating cover body 21 made of urethane foam as a resin foam member on the inner layer side, and an FRP provided in the outermost layer of the heat insulating cover body 21. A water vapor impermeable membrane layer 22 is provided, and elasticity is maintained at a low temperature as a seal member between the water vapor impermeable membrane layer 22 and the finned tube 3 at the lower end side portion of the heat insulating cover body 21. The seal portion 23 is made of EPDM or melamine foam, which is a rubber or resin member. Therefore, the panel upper header 1 and the vicinity of the connecting portion of the finned tube 3 have FR in the outer layer portion.
The heat insulating cover body 21 is surrounded by a urethane foam having a P layer, and at the lowermost end of the heat insulating cover body 21, a seal portion 23 ensures sufficient sealing performance. Then, as shown in FIG. 2, the outer layer portion of the water vapor impermeable membrane layer 22 in the vicinity of the connection portion of the finned tube 3 is configured as the seawater supply portion 6 described above. Here, the density of the urethane foam is 50 kg / m ³ or more, 200 k
It is set to g / m ³ or less, below which strength is weak and cracks occur at low temperatures, and above this,
Insufficient performance at low temperature, resulting in excessive weight.

Further, as shown in FIGS. 2 and 3, the above-described heat insulating cover 2 is divided into two parts along the axial direction of the panel upper header 1 at the upper part of the panel upper header 1, and The fixing portion 10 is provided at a predetermined position along the axial direction so that the heat insulating cover 2 can be attached and the seal can be secured. This fixed part 10 is specifically FR
Reinforced plastic nut 11 provided on the outer layer of P layer
And a bolt that is inserted into this and performs a fixing function (not shown)
Is. Further, the heat insulating cover 2 is divided into a plurality of pieces in the longitudinal direction, and the fixing portion 1 in this direction is divided.
2 is also provided. Further, as shown in FIG. 3, in the divided structure of the heat insulating cover 2, the division surface 13 formed along the axial direction of the panel upper header 1 is attached to the other side in the assembled state surrounding the panel upper header 1. An uneven portion 14 that fits and connects in the member is provided. further,
The dividing surface 15 in the longitudinal direction is also provided with the uneven portion 16.

Therefore, when the heat insulating cover 2 is attached, the heat insulating cover 2 is prepared by preparing a pair of members, fitting the concavo-convex portions 14 and 16 and fastening the fixing portion 10. Can be easily attached and detached.

[Other Embodiment] Another embodiment of the present application will be described below. (A) In the above embodiment, urethane foam was used as the resin foam member that constitutes the heat insulating cover body 21, but polyethylene foam, polystyrene foam, polyvinyl chloride foam, etc. are also used as such members. It is possible to When such a material is used, polyethylene foam has an advantage of good moldability, polystyrene foam has an advantage of being inexpensive, and polyvinyl chloride foam has an advantage of having high strength. (B) Further, when the heat insulating cover body 21 is made of urethane foam as described above, a low density urethane foam layer having a high degree of foaming is formed on the inner layer side in the radial direction of the panel upper header in the density of the urethane foam. It is preferable to provide a high-density urethane foam layer on the outer layer side. By adopting such a configuration, it is possible to mainly secure the heat insulating performance in the inner layer portion and to secure the strength and shape retention in the outer layer portion. (C) In the above examples, FRP was used as the water vapor impermeable membrane layer, but as such a member,
Aluminum plates, polyester sheets, vinyl chloride sheets, etc. can also be used. When such a material is used, the aluminum plate has the advantage that it becomes the same material as the internal piping and there is no fear of electrolytic corrosion, and it is lightweight, and the polyester sheet has the advantage of being inexpensive and highly moisture-proof. In the case of vinyl chloride sheet, there is an advantage that it is inexpensive and has high weather resistance. Furthermore, if a metal layer is provided as an outer layer of the FRP layer, the strength and shape retention of the heat insulating cover can be further secured. Similarly, even when a metal layer is attached alone instead of the FRP layer, the purpose of maintaining the strength and retaining the shape can be achieved.

In the claims, reference numerals are provided for convenience of comparison with the drawings, but the present invention is not limited to the configuration shown in the attached drawings.

[Brief description of drawings]

FIG. 1 is a perspective view of a main part of an open rack type carburetor.

FIG. 2 is a cross-sectional view near the panel upper header.

FIG. 3 is an exploded perspective view of a heat insulating cover.

FIG. 4 is a diagram showing a conventional heat insulating structure.

[Explanation of symbols]

 1 Panel Upper Header 2 Heat Insulation Cover 3 Finned Tube 6 Sea Water Supply Section 13 Dividing Surface 14 Concavo-convex Section 22 Water Vapor Impermeable Membrane Layer

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoshiharu Ishida 1-8-5 Kyomachibori, Nishi-ku, Osaka-shi, Osaka Within Meisei Industry Co., Ltd. (72) Hideyuki Hayashi 1-8-chome, Kyomachibori, Nishi-ku, Osaka-shi, Osaka No. 5 Inside Meisei Industry Co., Ltd. (72) Inventor Masahiro Morimoto 1-8-5, Kyomachibori, Nishi-ku, Osaka City, Osaka Prefecture Inside Meisei Industry Co., Ltd.

Claims (7)

[Claims] 1. A panel upper header (1) comprising liquefied natural gas flowing therein, and a plurality of finned tubes (3) extending downward from the panel upper header (1). ) And the finned tube (3) in the vicinity of the connection, the outer side of the finned tube (3) side is a seawater supply unit (6) for supplying seawater for heating. By the heat exchange of the liquefied natural gas advancing from the panel upper header (1) into the finned tube (3) with the seawater flowing down the outer surface of the finned tube,
A heat insulation structure of an open rack type vaporizer for obtaining natural gas by vaporizing in the finned tube, which is a resin foam member having a water vapor impermeable membrane layer (22) in an outer layer portion, and the panel upper header (1 ) And the vicinity of the connection part of the finned tube (3), and at the lower end side of the resin foam member, between the water vapor impermeable membrane layer (22) and the finned tube (3). ,
The heat insulating cover (2) is provided with a seal member made of rubber or resin member that retains elasticity at low temperature, and the outer layer portion of the resin foam member to the vicinity of the connection portion of the finned tube (3) is supplied with the seawater. Division (6)
Insulation structure of open rack type carburetor configured as. 2. The water vapor impermeable membrane layer (22) is FRP.
The heat insulating structure for an open rack vaporizer according to claim 1, wherein the heat insulating structure is a layer, the resin foam member is urethane foam, and the sealing member is EPDM or melamine foam. 3. The heat insulating cover (2) is divided into two parts above the panel upper header (1) along the axial direction of the panel upper header (1).
Insulated structure of the open rack type vaporizer described. 4. The heat insulating structure for an open rack vaporizer according to claim 2, wherein a metal layer is provided on an outer layer of the FRP layer. 5. The urethane foam has a density of 50 kg.
/ M ³ or more and 200 kg / m ³ or less is set, and the heat insulating structure of the open rack type carburetor according to claim 2. 6. In the density of the urethane foam,
The heat insulating structure for an open rack type vaporizer according to claim 2, wherein a urethane foam layer having a high density is provided on the outer side in the radial direction of the panel upper header (1). 7. In the divided structure of the heat insulating cover (2), a state in which the panel upper header (1) is surrounded by a dividing surface (13) formed along the axial direction of the panel upper header (1). The heat insulating structure for an open rack type carburetor according to claim 3, wherein a concavo-convex portion (14) for fitting and coupling is provided in the other member.