JP2013036634A - Heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a crack from occurring in an inner wall by thermal expansion of an outer cover.SOLUTION: An outer cylinder 11 and an inner cylinder 12 are arranged concentrically in a radius direction at an interval. A low-temperature gas passage L is formed between the outer cylinder 11 and inner cylinder 12. A high-temperature gas passage H is formed in the inner cylinder 12. The inner cylinder 12 is composed of a metal outer cover 21 and an inner wall 22 of a refractory material that coats the inner face of the metal outer cover 21. An anchor 31 is buried in the inner wall 22. The anchor 31 has an outer end part 41 supported by an outer cover inner face so that thermal expansion of the outer cover allows free deformation of an outer cover radial direction to occur.

Description

  The present invention relates to the thermal energy of high-temperature combustion gas (exhaust gas) generated in the process of incineration of waste in municipal waste incinerators and industrial waste incinerators and in the process of melting ash discharged from the incinerators. The present invention relates to a heat exchanging device that is recovered by exchanging and that makes effective use of heat energy.

  In this type of heat exchange device, an outer cylinder and an inner cylinder are arranged concentrically and spaced apart in the radial direction, a low temperature gas passage is provided between the outer cylinder and the inner cylinder, and a high temperature gas passage is provided in the inner cylinder. The inner cylinder is composed of a metal vertical outer shell and a fire-resistant inner wall coated on the inner surface of the outer shell, and the inner surface of the outer shell is known to have a refractory material attached thereto. (For example, refer to Patent Document 1).

  In this type of heat exchange device, the coefficient of thermal expansion of the metal shell is greater than the coefficient of thermal expansion of the refractory inner wall. Therefore, when the inner wall is pulled outward in the radial direction of the outer skin along with the thermal expansion of the outer skin, a tensile stress acts on the inner wall to generate a crack. If high temperature gas penetrates into the crack, it will cause high temperature corrosion of the outer skin and hinder the safe operation of the facility, and the cost of repairing the heat exchange device will be generated, which is not economical.

JP 2010-025375 A

  An object of the present invention is to provide a heat exchange device that can prevent the inner wall from cracking due to thermal expansion of the outer skin.

  In the heat exchange device according to the first aspect of the invention, the outer cylinder and the inner cylinder are concentrically arranged at a radial interval, and a low-temperature gas passage is provided between the outer cylinder and the inner cylinder, and a high-temperature gas is provided in the inner cylinder. Each of the passages is formed, and the inner cylinder is composed of a metal outer skin and an inner wall made of a refractory material coated on the inner surface of the outer skin, and an anchor is embedded in the inner wall. It has an outer end supported on the inner surface of the outer skin so as to freely deform in the radial direction.

  In the heat exchanging device according to the first aspect of the invention, even if the outer skin is deformed in the radial direction of the outer skin due to its thermal expansion, the deformation is not transmitted to the anchor and no tensile stress is applied to the inner wall. Therefore, it is possible to prevent the inner wall from cracking due to the deformation of the outer skin.

  Further, in the heat exchanging device according to the first aspect of the present invention, the engagement rod extends downward from the outer end of the anchor, the engagement rod is passed through the support frame, and the support frame can be protruded and retracted with respect to the inner wall. And having an inner frame member and an outer frame member that are opposed to each other in the radial direction of the outer skin with an interval greater than the deformation amount in the radial direction of the outer skin due to thermal expansion of the outer skin, and an anchor is placed on the inner frame member In addition, when the outer frame member is fixed to the inner surface of the outer skin, the anchor can be freely supported by the outer skin in the radial direction of deformation with a simple structure including only the support frame.

  In the heat exchange device according to the second aspect of the invention, the outer cylinder and the inner cylinder are concentrically arranged at a distance in the radial direction, and a low-temperature gas passage is provided between the outer cylinder and the inner cylinder, and a high-temperature gas is provided in the inner cylinder. Each of the passages is formed, and the inner cylinder is composed of a metal outer skin and an inner wall made of a refractory material coated on the inner surface of the outer skin, and the outer skin has a seam extending in the direction of the outer skin axis. The edge is configured to overlap with a width that is greater than the amount of deformation in the outer skin circumferential direction due to thermal expansion of the outer skin, and an anchor is embedded in the inner wall, and the anchor is in the outer circumferential direction due to thermal expansion of the outer skin. It has an outer end supported on the inner surface of the outer skin so that the deformation of the outer shell is free.

  In another heat exchanging device according to the second invention, when the outer skin is deformed by its thermal expansion, both edges of the seam are overlapped, so that the outer skin is not deformed in the radial direction. It is deformed in the circumferential direction, the deformation is not transmitted to the anchor, and no tensile stress is applied to the inner wall. Therefore, it is possible to prevent the inner wall from cracking due to the deformation of the outer skin.

  Furthermore, in another heat exchanging device according to the second invention, an engagement rod extends downward from the outer end of the anchor, the engagement rod is passed through the support frame, and the support frame is embedded in the inner wall. In addition, the inner frame member and the outer frame member sandwiching the engagement rod from the outer skin radial direction so as to freely move the engagement rod in the outer skin circumferential direction, and corresponding ends of the inner frame member and the outer frame member And a pair of side frame members opposed to each other in the outer skin circumferential direction with a larger interval than the deformation amount in the outer skin circumferential direction due to thermal expansion of the outer skin, and an anchor is mounted on the inner frame member, When the frame member is fixed to the inner surface of the outer skin, it is possible to freely support the deformation of the anchor in the outer circumferential direction with respect to the outer skin by a simple structure including only the support frame.

  According to this invention, the heat exchange apparatus which can prevent that a crack generate | occur | produces in an inner wall by the thermal expansion of an outer skin is provided.

It is a perspective view of the heat exchange apparatus by this invention. It is a vertical longitudinal cross-sectional view of the inner cylinder of the heat exchange device. FIG. 3 is a transverse cross-sectional view when the inner cylinder shown in FIG. 2 is cold. It is sectional drawing which follows the AA line of FIG. FIG. 3 is a transverse sectional view when the inner cylinder shown in FIG. 2 is hot. It is sectional drawing which follows the BB line of FIG. It is a cross-sectional view which shows the principal part of the inner cylinder by a modification. FIG. 8 is a transverse cross-sectional view when the inner cylinder shown in FIG. 7 is cold. It is sectional drawing which follows the CC line of FIG.

  Referring to FIG. 1, the outer cylinder 11 and the inner cylinder 12 are disposed concentrically and spaced apart in the radial direction. A low temperature gas passage L is formed between the outer cylinder 11 and the inner cylinder 12, and a high temperature gas passage H is formed in the inner cylinder 12, respectively.

  In FIG. 2, the outer cylinder 11 is omitted and only the inner cylinder 12 is shown. The inner cylinder 12 includes a metal vertical outer skin 21 and a refractory inner wall 22 covered on the inner surface of the outer skin 21. The thermal expansion coefficient of the outer skin 21 is larger than that of the inner wall 22.

  The upper end of the outer skin 21 is suspended by a hanger 24 at a fixed position 23. The lower end of the outer skin 21 is elastically received by the expansion 25. The expansion 25 is obtained by filling ceramic wool 27 inside the bellows-tube-shaped elastic member 26.

  A plurality of anchors 31 are embedded for each circumference on a plurality of circumferences provided at predetermined intervals in the height direction of the inner wall 22. Each anchor 31 is provided with a support frame 32.

  3 and 4 show the state of the anchor 31 and the periphery of the support frame 32 in the cold state, and FIGS. 5 and 6 show the state in the hot state in detail.

  The anchor 31 includes an anchor main body 42 extending in a Y-shape in a horizontal plane from the outer end 41 toward the inner wall 22 in the radial direction, and an engagement rod suspended from the outer end 41 along the outer surface of the inner wall 22. It consists of 43.

  The support frame 32 is a horizontal rectangular frame shape that is retractably accommodated in a radial recess 44 formed below the anchor body 42 on the outer surface of the inner wall 22 and through which the engagement rod 43 is passed. An inner frame member 51 and an outer frame member 52 that are opposed to each other with a gap in the radial direction, and a pair of side frame members 53 that connect corresponding ends of the inner frame member 51 and the outer frame member 52; And 54. The outer frame member 52 is fixed to the inner surface of the outer skin 21 by welding.

  When cold, the inner surface of the outer skin 21 and the outer surface of the inner wall 22 are substantially in contact with each other. Almost the entire support frame 32 is accommodated in the recess 44. The anchor main body 42 is placed on the inner frame member 51. The engaging rod 43 extends downward in the height direction near the outer frame member 52 in the middle of the length of the inner frame member 51 and the outer frame member 52.

  When hot, the outer skin 21 is expanded outward in the radial direction, but the expansion of the inner wall 22 is smaller than this. A gap is formed between the outer skin 21 and the inner wall 22 by the difference in expansion amount. As the outer skin 21 expands, the support frame 32 is moved together with the outer skin 21 outward in the radial direction of the outer skin 21. As a result, the support frame 32 is pulled out from the recess 44, and the engagement rod 43 is relatively moved to a position near the inner frame member 51 while the anchor body 42 slides on the inner frame member 51. The distance between the inner frame member 51 and the outer frame member 52 must be equal to or greater than the deformation amount in the radial direction of the outer skin 21 due to the thermal expansion of the outer skin 21. While the support frame 32 is pulled out from the recess 44, the inner wall 22 is supported by the support frame 32 via the anchor 31, but the tensile stress accompanying the thermal expansion of the outer skin 21 is applied to the inner wall 22. There is nothing.

  On the other hand, the outer skin 21 is expanded in the axial direction by the thermal expansion of the outer skin 21, but this is absorbed by the expansion 25.

  7 to 9 show another embodiment. FIG. 7 shows only a part of the outer skin 21 of the inner cylinder 12. A longitudinal seam 61 extending in the axial direction of the outer skin 21 is formed in a part of the outer skin 21 in the circumferential direction. A seam member 62 is provided on one edge of the seam 61. The seam member 62 has a cross-sectional contour U-shaped seal groove 63 in which the other edge of the seam 61 is slidably fitted in the outer skin 21 circumferential direction and the axial direction.

  In this embodiment, an anchor 71 and a support frame 72 shown in FIGS. 8 and 9 are used.

  The anchor 71 includes an anchor main body 82 extending in a V shape in the horizontal plane from the outer end portion 81 toward the center in the radial direction of the inner wall 22, and an engagement rod suspended from the outer end portion 81 along the outer surface of the inner wall 22. It consists of 83. In this modification, instead of the radial recess 44, a recess 84 that houses the support frame 72 is formed in the inner wall 22.

  The support frame 72 includes an inner frame member 91, an outer frame member 92, and a pair of side frame members 93 and 94, as in the above embodiment. The inner frame member 91 supports the anchor main body 82. The outer frame member 92 is fixed to the inner surface of the outer skin 21. The distance between the inner frame member 91 and the outer frame member 92 may be such that the engagement rod 83 is loosely clamped and the relative movement thereof is allowed. The distance between the side frame members 93 and 94 is set larger than the deformation amount in the circumferential direction of the outer skin 21 due to the thermal expansion of the outer skin 21.

  When the outer skin 21 is thermally expanded, the interval between the seams 61 is changed to be larger and smaller, and the outer skin 21 is deformed in the circumferential direction but cannot be deformed in the radial direction. Due to the circumferential deformation of the outer skin 21, the outer skin 21 and the inner wall 22 are moved relative to each other in the circumferential direction. Along with this movement, the engaging rod 83 is relatively moved in the support frame 72, so that no external force is applied to the inner wall 22 via the anchor 71. The inner wall 22 is inflated small outward in the radial direction, but is designed in advance so that the outer surface of the inner wall 22 is not pressed against the inner surface of the outer skin 21 due to expansion of the inner wall 22 in order to prevent cracking of the refractory material. There may be a gap between the outer surface of the inner wall 22 and the inner surface of the outer skin 21 when cold.

In the above two embodiments, any of the anchors 31 and 71 having the Y-shaped anchor body 42 or the V-shaped anchor body 82 may be used. Further, at the time of implementation, the anchors 31, 71 and the support frames 32, 72 are covered with wax, or the support frames 32, 72 are filled with wax so that the wax is burned or vaporized to disappear. In this case, the recesses 44 and 84 for accommodating the support frames 32 and 72 can be easily formed.

  The heat exchange apparatus according to the present invention is a thermal energy of high-temperature combustion gas (exhaust gas) generated in the process of incineration of waste in municipal waste incinerators and industrial waste incinerators and in the process of melting ash discharged from the incinerator. Is recovered by exchanging heat with air to achieve effective use of heat energy.

11 outer cylinder
12 inner cylinder
21 hull
22 inner wall
31 Anka
41 Anchor outer edge
L Low temperature gas passage
H Hot gas passage

Claims (4)

  The outer cylinder and the inner cylinder are arranged concentrically and spaced apart in the radial direction, a low temperature gas passage is formed between the outer cylinder and the inner cylinder, and a high temperature gas passage is formed in the inner cylinder. Consists of a metal outer skin and an inner wall made of a refractory material coated on the inner surface of the outer skin, and an anchor is embedded in the inner wall, so that the anchor is free to deform in the outer skin radial direction due to thermal expansion of the outer skin. A heat exchange device having an outer end supported on the inner surface of the outer skin.   An engagement rod extends downward from the outer end of the anchor, and the engagement rod is passed through the support frame. The support frame can protrude and retract with respect to the inner wall and is deformed in the outer skin radial direction due to thermal expansion of the outer skin. The inner frame member and the outer frame member are opposed to each other in the radial direction of the outer skin with an interval equal to or greater than the amount, the anchor is mounted on the inner frame member, and the outer frame member is fixed to the inner surface of the outer skin. The heat exchange device according to claim 1.   The outer cylinder and the inner cylinder are arranged concentrically and spaced apart in the radial direction, a low temperature gas passage is formed between the outer cylinder and the inner cylinder, and a high temperature gas passage is formed in the inner cylinder. Consists of a metal skin and an inner wall made of a refractory material coated on the inner surface of the outer skin. The outer skin has a seam extending in the direction of the outer skin axis, and both edges of the seam are the outer skin due to thermal expansion of the outer skin. It is configured so that it can overlap with a width equal to or greater than the amount of deformation in the circumferential direction, and an anchor is embedded in the inner wall, and the anchor has an inner surface that is free from deformation in the circumferential direction due to thermal expansion of the outer skin. A heat exchanging device having an outer end supported by the heat exchanger.   An engagement rod extends downward from the outer end of the anchor, and the engagement rod is passed through the support frame. The support frame is embedded in the inner wall and allows the engagement rod to freely move in the outer skin circumferential direction. The inner frame member and the outer frame member sandwiching the engaging rod from the outer skin radial direction, the corresponding ends of the inner frame member and the outer frame member are connected to each other, and the deformation amount in the outer skin circumferential direction due to the thermal expansion of the outer skin 4. A pair of side frame members that are opposed to each other in the outer circumferential direction with a larger interval, an anchor is placed on the inner frame member, and the outer frame member is fixed to the inner surface of the outer skin. The heat exchange apparatus as described in.

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