JP2016070375A - Joint structure of vacuum heat-insulating double pipe for low-temperature fluid - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a joint structure of vacuum heat-insulating double pipes for low-temperature fluid capable of securing heat-insulating performance while applying ordinary joint flanges.SOLUTION: A joint structure 10 of vacuum heat-insulating double pipes for low-temperature fluid is a joint structure of vacuum heat-insulating double pipes for low-temperature fluid having inner pipes (2a, 2b), and outer pipes (3a, 3b) externally fitted to the inner pipes (2a, 2b) through vacuum layers (4a, 4b), and includes a flange joint portion (20) for fastening a pair of joint flanges (21a, 21b) respectively disposed on connecting end portions of a pair of vacuum heat-insulating double pipes (1a, 1b) by a plurality of bolts (22a) and nuts (22b), an outer peripheral enclosure (30) surrounding prescribed length parts at connecting end sides of the pair of vacuum heat-insulating double pipes (1a, 1b) and an outer peripheral side of the flange joint portion (20) with an annular space (30a), and constituted to be partially detachable to enable fastening and unfastening the flange joint portion (20), and a vacuum layer formed in the annular space (30a).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a joint structure of a vacuum insulated double pipe for a cryogenic fluid.

  Conventionally, in piping for transporting low-temperature fluids such as various low-temperature liquefied gases, a vacuum heat insulating two-piece structure composed of an inner pipe and an outer pipe fitted with a cylindrical vacuum layer on the inner pipe is provided. Heavy pipes are known. When low-temperature liquefied gas (for example, liquefied helium, liquefied hydrogen, liquefied nitrogen, liquefied oxygen, etc.) is allowed to flow inside the inner tube, a vacuum layer is formed between the inner tube and the outer tube to prevent convective heat transfer. A vacuum heat insulating double tube utilizing the heat insulating effect of the vacuum layer is put into practical use.

  As a joint structure that connects the above vacuum heat insulation double pipe and vacuum heat insulation double pipe, a bayonet joint that can secure heat insulation performance by increasing the heat transfer distance from the joint flange that contacts the outside air to the inner pipe is practical. It is provided.

  In the bayonet joint described in Patent Document 1, a male-side joint portion having a small diameter is formed by a male-side inner tube and an outer tube, and the inside is made into a vacuum layer, and a female-side inner tube and an outer tube The female joint is inserted into the male joint, and the inside is made into a vacuum layer. The joint flange is provided on the diameter-reduced part of the outer pipe of the male joint, and the joint is attached to the end of the female joint. A flange is provided, and the male joint part is inserted into the female joint part with a minute cylindrical gap, and a pair of joint flanges are fastened with a plurality of bolts and nuts to bring the bayonet joint into a connected state.

  When transferring cryogenic fluid between a cryogenic fluid transport ship and onshore equipment, the loading arm on the land side is connected to the manifold of the cryogenic fluid piping on the ship via a bayonet joint to unload and load cryogenic fluid. I do. However, the male and female joints of the bayonet joint have a certain length which is long to a certain extent, and the minute gap between the two is a very small gap. It is very difficult to connect the female joint (or male joint) on the loading arm side to the joint (or female joint), it takes a lot of labor and time, and in the worst case, the bayonet joint is damaged. There is a case.

JP 2010-169185 A

  Therefore, as a joint structure of a vacuum insulated double pipe for cryogenic fluid, a joint flange is joined to the end of a vacuum insulated double pipe in the same manner as a joint flange of a normal single pipe. It is desirable to enable a normal type joint structure that is fastened with a plurality of bolts and nuts. However, when the above-described normal type joint structure is employed, the heat transfer distance from the joint flange in contact with the outside air to the inner pipe is shortened, and the necessary heat insulation performance cannot be ensured.

  An object of the present invention is to provide a joint structure of a vacuum insulated double pipe for low-temperature fluid that can ensure heat insulation performance while employing a normal joint flange.

  The joint structure of a vacuum insulated double pipe for cryogenic fluid according to claim 1 comprises an inner pipe and a vacuum insulated double pipe for cryogenic fluid having an outer pipe fitted with a vacuum layer between the inner pipe and the outer pipe. In the joint structure, a flange joint portion for fastening a pair of joint flanges respectively provided at a connection end portion of a pair of vacuum insulation double pipes by a plurality of fastening members, and a connection end of a pair of vacuum insulation double pipes An outer peripheral enclosure that surrounds an annular space between a predetermined length side portion and an outer peripheral side of the flange joint portion, at least a part of which is attachable and detachable to enable fastening and unfastening of the flange joint portion It is characterized by comprising an outer peripheral enclosure configured and a vacuum layer formed in the annular space.

  The joint structure of the vacuum heat insulating double pipe for low-temperature fluid according to claim 2 is the invention according to claim 1, wherein the outer peripheral enclosure includes a cylindrical member that surrounds the outer peripheral side of the flange joint portion and its vicinity. This cylindrical member is characterized in that it has a pair of semi-cylindrical members that are divided in two at the dividing plane including the axis of the vacuum heat insulating double tube and are detachable.

  The joint structure of the vacuum heat insulating double pipe for cryogenic fluid according to claim 3 is the invention according to claim 2, wherein the outer peripheral enclosure is a first divided body fixed to one of the vacuum heat insulating double pipes for low temperature fluid. The second divided body fixed to the other vacuum heat insulating double pipe for low-temperature fluid, and one end in the axial direction of the cylindrical member and the first divided body are flange-connected via a joint flange, The other axial end of the cylindrical member and the second divided body are flange-connected via a joint flange, and the circumferential ends of the pair of semi-cylindrical members are flange-connected via a connecting flange. It is a feature.

  According to a fourth aspect of the present invention, there is provided the joint structure of the vacuum heat insulating double pipe for cryogenic fluid according to the first aspect of the invention. It is characterized by comprising a pair of divided enclosures configured to be detachable.

  The joint structure of the vacuum insulated double pipe for cryogenic fluid according to claim 5 is the invention according to claim 4, wherein the pair of semicircular arc plates respectively joined to both end portions in the axial center direction of the divided enclosure are one pair. A pair of connecting flanges joined to the outer peripheral surface of the vacuum heat insulating double tube are respectively fastened by a plurality of fastening members, and the circumferential ends of the pair of split enclosures are connected via a pair of connecting flanges. The vacuum insulated double tube for cryogenic fluid according to claim 4, wherein the vacuum insulated double tube is fastened by a plurality of fastening members.

  According to the first aspect of the present invention, the flange joint portion for fastening the pair of joint flanges respectively provided at the connection end portions of the pair of vacuum heat insulation double tubes by the plurality of fastening members, and the pair of vacuum heat insulation doubles Since it includes an outer peripheral side enclosure surrounding the pipe connecting end side with a predetermined length and an outer peripheral side of the flange joint portion with an annular space therebetween, and a vacuum layer formed in the annular space, In addition, the outer enclosure and the flange joint can be insulated, and a sufficient heat transfer distance can be secured to transfer heat from the outer enclosure to the joint flange through the outer tube.

  In addition, since the outer peripheral enclosure is configured to be at least partially detachable so as to enable the fastening and fastening release of the flange joint portion, it provides support for fastening and fastening release of the flange joint portion. There is no.

  According to invention of Claim 2, the said outer peripheral side enclosure has the cylindrical member which surrounds the outer peripheral side of the said flange joint part and its vicinity part, This cylindrical member contains the axial center of a vacuum heat insulation double tube | pipe. Since it has a pair of semi-cylindrical members that are split into two on the dividing surface and configured to be detachable, a small and lightweight pair of semi-cylindrical members can be attached and detached when fastening and releasing the flange joint. Therefore, workability can be improved.

  According to the invention of claim 3, in the invention of claim 2, the space between the first and second divided bodies is covered with the cylindrical member, and both end portions of the cylindrical member are jointed to the first and second divided bodies. Since the flange connection is performed via the flanges and the circumferential ends of the pair of semi-cylindrical members are flange-connected via the connection flanges, airtightness can be ensured through these flange connections.

  According to invention of Claim 4, the said outer peripheral side enclosure consists of a pair of division | segmentation enclosure divided | segmented into 2 by the division surface containing the axial center of the vacuum heat insulation double pipe | tube for cryogenic fluids, and was comprised so that attachment or detachment was possible. Therefore, the structure of the outer peripheral side enclosure can be simplified.

  According to the invention of claim 5, in the invention of claim 4, the semicircular circular arc plates at both ends in the axial center direction of the divided enclosure are paired with the outer peripheral surfaces of a pair of vacuum heat insulating double tubes. Since the circumferential end portions of the pair of divided enclosures are fastened by a plurality of fastening members via a pair of connection flanges, the flange joint portions are separated. In this state, the outer peripheral enclosure can be removed from the vacuum heat insulating double tube.

It is sectional drawing of the joint structure of the vacuum heat insulation double pipe | tube for cryogenic fluids concerning Example 1 of this invention. It is the II-II sectional view taken on the line of FIG. It is sectional drawing of the joint structure of the vacuum heat insulation double tube for cryogenic fluids concerning Example 2. FIG. It is the IV-IV sectional view taken on the line of FIG. It is a fragmentary perspective view of the division | segmentation enclosure of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

As shown in FIG. 1 and FIG. 2, the vacuum heat insulation double tube 1 for cryogenic fluid is a double tube for transporting liquefied gas (liquefied helium, liquefied hydrogen, liquefied nitrogen, liquefied oxygen, etc.) which is a cryogenic fluid. is there.
A pair of vacuum heat insulation double pipes 1a and 1b connected via the joint structure 10 of the vacuum heat insulation double pipe for low-temperature fluid of the present application includes inner pipes 2a and 2b, and cylindrical pipes on the inner pipes 2a and 2b. The outer pipes 3a and 3b are concentrically fitted with the vacuum layers 4a and 4b. Internal passages 5a and 5b for transporting liquefied gas are formed inside the inner pipes 2a and 2b. Although not shown, a super insulation for blocking radiant heat is wound around the outer circumference of the inner pipes 2a and 2b.

  The inner pipes 2a and 2b are made of stainless steel or aluminum alloy, and the outer pipes 3a and 3b are made of ordinary steel or stainless steel, and the outer diameters and plate thicknesses of the inner pipes 2a and 2b and the outer pipes 3a and 3b. Is appropriately set according to the use of the vacuum heat insulating double tube 1.

Next, the joint structure 10 of the present application will be described.
The joint structure 10 includes a flange joint portion 20, an outer peripheral side enclosure 30 that surrounds the outer peripheral side of the flange joint portion 20 with an annular space 30a therebetween, and a vacuum layer formed in the annular space 30a. The flange joint portion 20 has a structure in which a pair of joint flanges 21a and 21b provided at connection ends of a pair of vacuum heat insulating double tubes 1a and 1b are fastened by a plurality of bolts 22a and nuts 22b (fastening members). It has become.

  The joint flanges 21a and 21b are arranged orthogonal to the axis X of the vacuum heat insulating double pipe 1, and the inner pipe 2a of the vacuum heat insulating double pipe 1a is joined to the inner peripheral part of the joint flange 21a, and the outer pipe 3a. Is joined to the middle part of the joint flange 21a in the radial direction, the inner pipe 2b of the vacuum heat insulating double pipe 1b is joined to the inner peripheral part of the joint flange 21b, and the outer pipe 3b is joined to the middle part of the joint flange 21b in the radial direction. In addition, a seal member 23 such as an O-ring is mounted in an annular seal groove formed in the inner peripheral portion of the joint flange 21b. The joint flanges 21a and 21b are fastened by a plurality of bolts 22a and nuts 22b in a state where the joint flanges 21a and 21b of the vacuum heat insulating double pipes 1a and 1b are abutted.

  The outer peripheral side enclosure 30 surrounds the connection end side predetermined length portion of the pair of vacuum heat insulating double tubes 1a and 1b and the outer peripheral side of the flange joint portion 20 with an annular space 30a therebetween, and this outer peripheral side enclosure The body 30 is configured to be at least partially detachable so that the flange joint portion 20 can be fastened and unfastened. The outer periphery side enclosure 30 is comprised so that a vacuum layer can be formed with plain steel or stainless steel.

  The outer peripheral enclosure 30 includes a first divided body 31 fixed to one vacuum heat insulating double pipe 1a, a second divided body 32 fixed to the other vacuum heat insulating double pipe 1b, and first and second. A flange member 20 and a cylindrical member 33 that surrounds the outer peripheral side of the vicinity of the flange joint portion 20 are provided so as to block between the divided bodies 31 and 32. The cylindrical member 33 has a pair of semi-cylindrical members 33U and 33L that are divided into two by a dividing surface A including the axis X and are detachable.

  The first divided body 31 has an inner peripheral end joined to the outer peripheral surface of the double pipe 1a and an annular plate 31a orthogonal to the axis X, and one end joined to the outer peripheral end of the annular plate 31a. A cylindrical body 31b extending to the 20 side and a joint flange 31c joined to the other end of the cylindrical body 31b are provided. The second divided body 32 has an inner peripheral end joined to the outer peripheral surface of the double pipe 1b and an annular plate 32a orthogonal to the shaft center X, and one end joined to the outer peripheral end of the annular plate 32a. A cylindrical body 32b extending to the 20 side and a joint flange 32c joined to the other end of the cylindrical body 32b are provided. A seal member 34 such as an O-ring is mounted in a seal groove formed in the inner peripheral portion of the joint flanges 31c and 32c.

  A joint flange 33a is joined to one end (left end) in the axial direction of the cylindrical member 33, a joint flange 33b is joined to the other end (right end) in the axial direction of the cylindrical member 33, and the joint flange 31c and the joint are joined. The flange 33a is fastened by a plurality of bolts 35a and nuts 35b (fastening members), and the joint flange 32c and the joint flange 33b are fastened by a plurality of bolts 36a and nuts 36b (fastening members).

  Further, connection flanges 37 and 37 are joined to both ends in the circumferential direction of the pair of semi-cylindrical members 33U and 33L, respectively, and the circumferential ends of the pair of semi-cylindrical members 33U and 33L are connected to the connection flange 37, 37, respectively. 37 is connected via a flange. As shown in FIG. 2, a pair of upper and lower connection flanges 37, 37 are fastened with a plurality of bolts 38 a and nuts 38 b (fastening members) on the left side of the shaft center X, and a pair of upper and lower connection flanges on the right side of the shaft center X. 37 and 37 are fastened by a plurality of bolts 38a and nuts 38b (fastening members). A seal member 39 such as an O-ring is attached to the seal groove formed in the upper connection flange 37.

  The operation and effect of the joint structure 10 of the vacuum heat insulating double pipe for cryogenic fluid described above will be described. A flange joint 20 for fastening a pair of joint flanges 21a and 21b, which are provided at connection ends of the pair of vacuum heat insulation double tubes 1a and 1b, respectively, by a plurality of bolts 22a and nuts 22b, and a pair of vacuum heat insulation two Since it includes the outer peripheral side enclosure 30 that surrounds the annular space 30a with a predetermined length portion on the connection end side of the heavy pipes 1a and 1b and the outer peripheral side of the flange joint portion 20, and a vacuum layer formed in the annular space 30a. In addition, the outer envelope 30 and the flange joint 20 are insulated from each other through the vacuum layer, and the heat transfer distance for transferring heat from the outer envelope 30 to the joint flanges 21a and 21b through the outer tubes 3a and 3b is increased. It is possible to secure sufficient heat insulation performance.

  Moreover, since the outer peripheral side enclosure 30 is configured to be at least partly detachable so as to enable the fastening and fastening release of the flange joint portion 20, it provides support for fastening and fastening release of the flange joint portion 20. There is no.

  The outer peripheral side enclosure 30 has a cylindrical member 33 that surrounds the outer peripheral side of the flange joint portion 20, and this cylindrical member 33 is divided into two by a dividing plane A including the axis X of the vacuum heat insulating double tubes 1 a and 1 b. Since the pair of semi-cylindrical members 33U and 33L are configured to be detachable, the pair of small and lightweight semi-cylindrical members 33U and 33L can be attached and detached when the flange joint 20 is fastened and released. Therefore, workability can be improved.

  The space between the first and second divided bodies 31 and 32 is covered with a cylindrical member 33, and both end portions of the cylindrical member 33 are connected to the first and second divided bodies 31 and 32 with joint flanges 31c and 33a; 32c and 33b. And the circumferential ends of the pair of semi-cylindrical members 33U and 33L are flange-connected through the connection flanges 37 and 37, so that airtightness can be ensured through these flange connections. it can.

  In the vacuum heat insulating double pipe joint structure 10A for cryogenic fluid of this embodiment, the structures of the vacuum heat insulating double pipes 1a and 1b for cryogenic fluid and the flange joint portion 20 are the same as those of the first embodiment. Since only the mounting structure 40 is different from the mounting structure 40, the same components are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIGS. 3 to 5, the outer periphery side enclosure 40 has an annular space 40 a between the connection end side predetermined length portion of the pair of vacuum heat insulating double tubes 1 a and 1 b and the outer peripheral side of the flange joint portion 20. The outer periphery side enclosure 40 is configured to be at least partially detachable so that the flange joint portion 20 can be fastened and unfastened. The annular space 40a is a vacuum layer.

The outer peripheral enclosure 40 is composed of a pair of divided enclosures 40U and 40L that are divided into two by a dividing plane B including the axis X of the vacuum heat insulating double tubes 1a and 1b for low-temperature fluid and are detachable.
Since the pair of divided enclosures 40U and 40L are symmetrical in the vertical direction, the upper divided enclosure 40U will be described. The divided enclosure 40U includes a semi-cylindrical body 41 having an open lower end, and a pair of left and right semicircular arc plates 42a and 42b joined to both left and right ends of the semi-cylindrical body 41, and is orthogonal to the axis X. A pair of semicircular arc plates 42a and 42b, a connection flange 43 joined to both ends in the circumferential direction of the semicylindrical body 41, and a flange joint joined to the lower ends of the pair of semicircular arc plates 42a and 42b. A connecting flange 44 extending to the opposite side to the portion 20 is provided. A seal member 45 such as an O-ring is attached to the seal groove formed in the upper connection flanges 43 and 44.

  Annular connection flanges 46a and 46b are joined to the outer peripheral surfaces of the pair of vacuum heat insulating double tubes 1a and 1b so as to contact the inner surfaces of the pair of left and right semicircular arc plates 42a and 42b. A pair of semicircular arc plates 42a and 42b at both axial ends of the divided enclosure 40U are provided with a plurality of bolts 47a and a pair of connection flanges 46a and 46b fixed to the outer peripheral surfaces of the double tubes 1a and 1b. It is fastened with a nut 47b (fastening member). The same applies to the divided enclosure 40L.

A seal member 46s such as an O-ring is mounted in a seal groove formed at the inner peripheral portion of the connection flanges 46a and 46b. The nut 47b is fixed in advance to the connection flanges 46a and 46b.
The circumferential ends of the pair of divided enclosures 40U and 40L are fastened by a plurality of bolts 48a and nuts 48b (fastening members) via a pair of connection flanges 43 and 43. The connection flanges 44 at the ends of the pair of semicircular arc plates 42a and 42b are fastened by a plurality of bolts 49a and nuts 49b (fastening members).

  The operation and effect of the joint structure 10A for the vacuum heat insulating double pipe for cryogenic fluid described above will be described. The outer peripheral side enclosure 40 is composed of a pair of divided enclosures 40U and 40L which are divided into two parts by a split surface B including the axis X of the vacuum heat insulating double tube 1 for cryogenic fluid and are detachable. The structure of the side enclosure 40 can be simplified.

  A plurality of semicircular arc plates 42a and 42b at both axial ends of the divided enclosures 40U and 40L are provided on a pair of connection flanges 46a and 46b joined to the outer peripheral surfaces of the pair of vacuum heat insulating double tubes 1a and 1b. The bolts 47a and nuts 47b are respectively fastened, and the circumferential ends of the pair of divided enclosures 40U and 40L are fastened by a plurality of bolts 48a and nuts 48b via a pair of connection flanges 43 and 43. Therefore, in a state where the flange joint portion 20 is separated, the outer peripheral side enclosure 40 can be removed from the vacuum heat insulating double tubes 1a and 1b.

An example in which the embodiment is partially changed will be described.
1) The outer periphery side enclosures 30 and 40 are provided with pipe connection fittings for evacuating in order to form a vacuum layer.
2) Structure that intentionally lengthens the outer tubes 3a and 3b (the outer tube 3a from the annular plate 31a to the joint flange 21a and the outer tube 3b from the annular plate 32a to the joint flange 21b) inside the outer peripheral side enclosure 30 (For example, a bellows structure or the like) may be provided. Thereby, a heat transfer distance can be enlarged and the higher heat insulation performance can be provided.
3) In addition, those skilled in the art can implement the present invention by adding various modifications to the above embodiment, and the present invention includes such modifications.

  An object of the present invention is to provide a joint structure for a vacuum insulated double pipe for low-temperature fluid that can ensure heat insulation performance while employing a normal joint flange.

1a, 1b Vacuum insulated double pipes for low temperature fluids 2a, 2b Inner pipes 3a, 3b Outer pipes 4a, 4b Vacuum layer 10, 10A Joint structure 20 of vacuum insulated double pipes for low temperature fluids Flange connection parts 21a, 21b Joint flange 22a , 22b Bolts, nuts 30, 40 Outer enclosures 30a, 40a Annular spaces 31, 32 First and second divided bodies 31c, 33a Joint flanges 32c, 33b Joint flanges 33 Cylindrical members 33U, 33L Semi-cylindrical members 37 Connection flanges 40U , 40L Semi-circular circular arc plate 43 Connection flanges 46a, 46b Connection flanges 47a, 47b Bolts, nuts 48a, 48b Bolts, nuts 49a, 49b Bolts, nuts

Claims (5)

In a joint structure of a vacuum insulated double pipe for low-temperature fluid having an inner pipe and an outer pipe fitted with a vacuum layer between the inner pipe and the outer pipe,
A flange joint portion for fastening a pair of joint flanges respectively provided at connection ends of a pair of vacuum heat insulating double pipes by a plurality of fastening members;
An outer peripheral enclosure that encloses a predetermined length portion of the connection end side of the pair of vacuum heat insulating double pipes and the outer peripheral side of the flange joint portion with an annular space therebetween, and enables fastening and release of the flange joint portion. An outer periphery-side enclosure configured to be at least partially detachable so as to
A joint structure for a vacuum insulated double pipe for low-temperature fluid, comprising a vacuum layer formed in the annular space.   The outer peripheral enclosure has a cylindrical member that surrounds the outer peripheral side of the flange joint portion and the vicinity thereof, and this cylindrical member is divided into two by a dividing surface including the axis of the vacuum heat insulating double tube and is detachable The joint structure of a vacuum insulated double pipe for cryogenic fluid according to claim 1, wherein the joint structure has a pair of semi-cylindrical members. A first divided body fixed to one of the vacuum insulated double tubes for low-temperature fluid,
A second divided body fixed to the other vacuum insulated double tube for low-temperature fluid,
One end of the cylindrical member in the axial direction and the first divided body are flange-connected via a joint flange, and the other axial end of the cylindrical member and the second divided body are flange-connected via a joint flange. The joint structure of a vacuum insulated double pipe for low-temperature fluid according to claim 2, wherein the circumferential ends of the pair of semi-cylindrical members are flange-connected via a connection flange.   The said outer peripheral side enclosure consists of a pair of division | segmentation enclosure divided | segmented into 2 by the division surface containing the axial center of the vacuum heat insulation double pipe | tube for cryogenic fluids, and was comprised so that attachment or detachment was possible. The joint structure of the vacuum heat insulation double pipe for low-temperature fluids of description.   A pair of semicircular arc plates joined respectively to both axial ends of the divided enclosure are a plurality of fastening members on a pair of connection flanges joined to the outer peripheral surface of a pair of vacuum heat insulating double tubes. The vacuum heat insulation for cryogenic fluid according to claim 4, wherein the ends of the pair of divided enclosures in the circumferential direction are fastened by a plurality of fastening members via a pair of connection flanges. Double pipe joint structure.