JP2004037020A - Heat exchanger and heat exchange type reactor using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve reliability in a sealing structure for sealing fluid and to reduce manufacturing costs. <P>SOLUTION: The heat exchanger comprises: a cylindrical external cylinder 2; an internal cylinder 5 provided at the central section of the outer cylinder 2; a plurality of tubes 3 for heat exchange that are provided so that they become a plurality of spirals being extended radially from the outer periphery section of the internal cylinder 5; separators 4, 4 that are provided at both the end sections of the external cylinder 2, support both the end sections of each tube 3, partition tube inner space and tube outer space, and prevent the mixture of the fluid; a fin that is provided at the tube inner space and/or tube outer space; and pipes P1, P2 that communicate with either the tube inner space or the tube outer space to form the inlet/outlet of the fluid. Heat is exchanged by circulating fluid to the tube inner space and the tube outer space. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a heat exchanger and a heat exchange reactor using the same, and more specifically, a plurality of tubes for heat exchange arranged in a spiral form extending radially outward from the center thereof. The present invention relates to a heat exchanger and a heat exchange reactor using the same.
[0002]
[Prior art]
The heat exchanger has various uses such as cooling, heating, and evaporating a fluid, and is widely used in industry.
As a technique close to the present invention, a regenerative heat exchanger for a gas turbine as shown in FIG. This heat exchanger 100 has a donut shape in which a fin 101 bent in an involute curve is laminated on an outer peripheral portion of a turbine body, and a fluid a (heating fluid) and a fluid b (fluid to be heated) flow countercurrently to exchange heat. (See U.S. Pat. No. 4,093,330).
[0003]
As a heat exchange reactor with a catalyst, there is known a heat exchange reactor 200 mainly using a square finned plate heat exchanger as shown in FIG. 10 (b). In this heat exchange reactor 200, a fin 201 (or 202) carrying a catalyst is joined to a plate, and these are laminated so that heat exchange between the fluid a 'and the fluid b' can be carried out by cross flow. (See Japanese Patent Application Laid-Open No. 2000-203801).
[0004]
[Problems to be solved by the invention]
However, the conventional technique has the following problems.
(1) In general, a regenerative heat exchanger for a gas turbine has many seal points for shutting off a heating fluid and a fluid to be heated so as not to mix with each other.
(2) In addition to the above problems, there is a problem that the structure of a single component is complicated, the number of components is large, and the manufacturing cost is high.
[0005]
(3) Furthermore, general heat exchangers are kept warm to reduce heat loss to the outside regardless of various types. However, since a large amount of heat insulating material is used, the size of the entire heat exchanger is large. However, there was a problem that the size eventually became larger than it actually was. In addition, the cost of the heat insulation was also high.
[0006]
(4) When a square-shaped finned plate heat exchanger is used as the heat exchange reactor 200, since the corners are connected by a flat plate, the outside exposed to the outside of the internal volume of the heat exchanger is connected. Since the surface area increases, energy loss to the outside due to heat radiation increases. Further, when an abnormal pressure is generated inside the rectangular finned plate heat exchanger, the pressure cannot be uniformly distributed inside, so that it is disadvantageous in pressure resistance. Therefore, if the plate thickness is increased to increase the rigidity of the square finned plate heat exchanger, the weight increases and the heat capacity increases. There was a problem of becoming long.
(5) In addition, there is only a rectangular heat exchange reactor as a conventional heat exchange reactor with a stacked-type catalyst. Due to the shape of the reactor, there are four corners where fluid hardly flows. There was a problem that the performance of the catalyst could not be obtained.
[0007]
The present invention has been made to solve the above-described problems, and a first object of the present invention is to provide a heat exchanger having a highly reliable sealing structure for sealing a fluid and having a low manufacturing cost. is there. Further, a second object is to provide a heat exchanger which has a small heat loss to the outside and a high pressure resistance in addition to the first object, and which can improve the heat exchange efficiency between fluids. With the goal. A third object is to provide a heat exchange reactor utilizing the merits of the heat exchanger in addition to the second object.
[0008]
[Means for Solving the Problems]
The heat exchanger according to claim 1, which has been made to solve the problem, a cylindrical outer cylinder, an inner cylinder provided at the center of the outer cylinder, and provided inside the outer cylinder, A plurality of tubes for heat exchange each arranged so as to be a plurality of spirals extending radially from the outer periphery of the inner cylinder, and provided at both ends of the outer cylinder, A separator that supports and separates the inner space of the tube and the outer space of the tube and prevents mixing of fluid; a fin provided in the inner space of the tube and / or the outer space of the tube; and a fin provided in the inner space of the tube or the outer space of the tube. And a pipe that communicates with one of the tubes to form an inlet / outlet for the fluid, and allows the fluid to flow through each of the inner space of the tube and the outer space of the tube to exchange heat.
[0009]
According to the invention described in claim 1,
(1) By making the outer cylinder cylindrical, the stress generated by the internal pressure can be dispersed uniformly, so that the pressure resistance is improved as compared with the square shape. Further, since the outer cylinder has a cylindrical shape, and the outer surface area exposed to the outside with respect to the internal volume of the heat exchanger can be made smaller than that of the square shape, heat loss can be reduced as compared with the square shape.
(2) Since the inner cylinder is hollow and lighter than a solid, the weight of the heat exchanger can be reduced.
(3) By providing a plurality of tubes for heat exchange, each of which is arranged so as to form a plurality of spirals extending radially from the outer peripheral portion of the inner tube, the flow of the tube space in the radial direction in the outer tube is provided. Since the cross-sectional area of the passage and the cross-sectional area of the flow passage of the outer tube space can be made substantially the same, the fluid flowing through each space is evenly distributed. As a result, the heat exchange efficiency between the fluids is improved.
(4) By providing separators provided at both ends of the outer cylinder to support both ends of each of the tubes and partition a space inside the tube and a space outside the tube to prevent mixing of fluids, Not only is it easy to assemble, but also the reliability of the seal structure is improved. In addition, since the number of sealing portions is small, the number of parts when assembling can be reduced. As a result, manufacturing costs can be reduced.
(5) By providing the fins in the space inside the tube and / or the space outside the tube, the fluid is disturbed by the fins, and the heat exchange efficiency between the fluids is improved.
(6) By providing a pipe that communicates with either the inner space of the tube or the outer space of the tube and forms an inlet / outlet for the fluid, the fluid can be smoothly introduced and discharged to and from the heat exchanger.
[0010]
The heat exchanger according to claim 2 is the heat exchanger according to claim 1, wherein a vacuum heat insulating layer is provided around the outer cylinder.
[0011]
According to the second aspect of the present invention, by providing the vacuum heat insulating layer around the outer cylinder, it is possible to form a heat exchanger with less heat loss from the inside of the outer cylinder to the outside. Further, a heat insulating material is not required, and the production cost can be reduced.
[0012]
The heat exchanger according to claim 3, wherein the outer surface of the tube is provided with a rib extending in a radial direction of the outer cylinder when the tube is provided inside the outer cylinder. A heat exchanger according to claim 1 or claim 2.
[0013]
According to the invention described in claim 3, when the tube is provided inside the outer tube on the outer surface of the tube, by providing a rib extending in the radial direction of the outer tube,
(1) When a plurality of tubes for heat exchange are provided inside the outer cylinder and the fins are filled in the tube outer space formed by the tubes, the fins can be easily positioned.
(2) Since the flow path is narrowed by the rib, when the fluid flows through the outer space of the tube, the pressure increases on the upstream side of the rib, and the fluid spreads along the outer surface of the tube by the force of this pressure. become. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
[0014]
A heat exchange reactor described in claim 4 is a heat exchange reactor equipped with the heat exchanger according to any one of claims 1 to 3, wherein the fin is replaced with the fin. Wherein a metal honeycomb is provided, and a catalyst is supported on the surface of the metal honeycomb.
[0015]
According to a fourth aspect of the present invention, there is provided a heat exchange reactor including the heat exchanger according to any one of the first to third aspects, wherein a metal honeycomb is used instead of the fin. Is provided, and the catalyst is carried on the surface of the metal honeycomb. As a result, the flow rate of the fluid flowing through the metal honeycomb can be increased, and the surface area per volume can be increased. And a cylindrical heat-exchange reactor having a large catalyst-supporting area.
This heat exchange reactor is
(1) Compared to a square heat exchange reactor, because it has a cylindrical shape and the external surface area exposed to the outside with respect to the internal volume of the heat exchange reactor can be made smaller than that of a square heat exchange reactor. Heat loss can be reduced.
(2) Since the outer cylinder is formed in a cylindrical shape, the stress generated by the internal pressure can be dispersed uniformly, so that the pressure resistance is higher than that of a square heat exchange type reactor.
(3) Since the outer cylinder is formed in a cylindrical shape, there are no portions in which the fluid does not easily flow at the four corners, unlike a square heat exchange reactor. Therefore, since the fluid and the catalyst are in sufficient contact, the performance of the catalyst can be improved as compared with a square heat exchange reactor.
Here, the “metal honeycomb” is a honeycomb member made of a metal material.
[0016]
The heat exchange reactor according to claim 5 is the heat exchange reactor according to claim 4, wherein a vacuum heat insulating layer is provided around the outer cylinder.
[0017]
According to the invention described in claim 5, by providing the vacuum heat insulating layer around the outer cylinder, it is possible to form a heat exchange reactor having less heat loss from the inside of the outer cylinder to the outside. Further, a heat insulating material is not required, and the production cost can be reduced.
[0018]
In the heat exchange reactor according to claim 6, when the tube is provided inside the outer tube, a rib extending in a radial direction of the outer tube is provided on an outer surface of the tube. A heat exchange reactor according to claim 4 or claim 5, characterized in that:
[0019]
According to the invention described in claim 6, when the tube is provided inside the outer tube on the outer surface of the tube, a rib extending in the radial direction of the outer tube is provided, so that the outer tube is provided. Positioning when inserting the metal honeycomb into the space is facilitated. Also, since the flow path is narrowed by the rib, when the fluid flows into the outer space of the tube, the pressure increases on the upstream side of the rib, and the force of this pressure causes the fluid to spread over the entire outer surface of the tube. Become. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
[0020]
The invention described in claim 7 is provided with a combustion catalyst that uses a combustible gas as a heat medium by catalytically combusting a combustible gas inside the inner cylinder, and the heat medium generated by the combustion catalyst is provided on the metal honeycomb. Not to supply to the inner tube space or the outer tube space, and to supply reformed raw fuel to the inner tube space or the outer tube space provided with the metal honeycomb, using heat from the heat medium. A reforming reactor using the heat exchange reactor according to any one of claims 4 to 6, wherein the reforming raw fuel is reformed.
[0021]
According to the invention described in claim 7, a combustion catalyst is provided inside the inner cylinder as a heat medium by catalytically combusting a combustible gas, and the heat medium generated by the combustion catalyst is provided on the metal honeycomb. Not supplied to the inner tube space or the outer tube space, and the reformed raw fuel is supplied to the inner tube space or the outer tube space provided with the metal honeycomb, and heat from the heat medium is used. By reforming the reformed raw fuel in this manner, the heat medium and the reformed raw fuel are evenly distributed, and the heat exchange efficiency between the heat medium and the reformed raw fuel is increased. A high reforming reactor can be formed.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is an overall configuration diagram showing an embodiment of the heat exchanger according to the present invention, FIG. 2 is a perspective view of the outer periphery of an outer cylinder of the heat exchanger according to the present invention, and FIG. 2 and FIG. 3B is a cross-sectional view taken along line AA of FIG. 3A.
4A is a view for explaining the shape of the tube according to the present invention, FIG. 4B is a three-dimensional view of the tube, FIG. 5 is an outline view of various fins according to the present invention, FIG. 6 is a partial cross-sectional view for explaining the structure of the connecting portion between the tube and the separator.
FIG. 7A is a diagram for explaining the flow of gas in the heat exchanger when the inlet and outlet of the fluid flowing outside the tube are on the outer peripheral portion of the outer cylinder. FIG. FIG. 4 is a diagram for explaining a gas flow in the heat exchanger when the inlet / outlet of a fluid flowing through the heat exchanger is at the outer peripheral portion of the inner cylinder.
FIG. 8 is a diagram for explaining the surface temperature distribution of a tube according to the heat exchanger of the present invention, and FIG. 9 is a diagram illustrating an example in which the heat exchange reactor according to the present invention is used as a reforming reactor. It is a figure for explaining an example.
[0023]
A heat exchanger 1 according to an embodiment of the present invention, as shown in FIG.
A cylindrical outer cylinder 2; an inner cylinder 5 provided at the center of the outer cylinder 2; and a plurality of spiral lines provided inside the outer cylinder 2 and extending radially from the outer periphery of the inner cylinder 2. As described above, a plurality of tubes 3 for heat exchange, each of which is disposed, and provided at both ends of the outer tube 2 to support both ends of each tube 3 and form a space inside the tube and a space outside the tube. Separators 4 and 4 for preventing the mixing of the partition fluid, fins 3fi and 3fo provided in the inner space and the outer space of the tube (see FIG. 3B), and any of the inner space and the outer space of the tube. A main part is constituted by pipes P1 and P2 which communicate with one of them and form an inlet / outlet of the fluid.
[0024]
The outer cylinder 2 has a cylindrical shape as shown in FIG. 2. When the inlet / outlet of the fluid flowing outside the tube 3 is at the outer peripheral portion of the outer cylinder 2 as in the present embodiment, FIGS. As shown in FIG. 3, a plurality of bleed holes 2a and 2b are provided along the circumferential direction of both ends of the outer cylinder 2.
By forming the outer cylinder 2 in a cylindrical shape in this manner, the stress generated by the internal pressure can be uniformly dispersed, so that the pressure resistance is improved as compared with a square shape. In addition, since the heat exchanger 1 has a cylindrical shape, the external surface area exposed to the outside with respect to the internal volume of the heat exchanger 1 can be made smaller than that of the square shape, so that heat loss can be reduced as compared with the square shape.
[0025]
An air jacket 6 as shown in FIGS. 1 and 7A is provided outside the outer cylinder 2, and a vacuum heat insulating layer 7 as shown in FIG. (However, the vacuum heat insulating layer 7 is not provided in the heat exchanger of FIG. 1).
The vacuum heat-insulating layer 7 forms two rooms partitioned outside the air jacket 6, and can be manufactured by using a vacuum in a vacuum furnace when brazing members. Further, since the vacuum heat insulating layer 7 is formed in a cylindrical shape, there is an advantage that stress due to vacuum is uniformly distributed over the entire circumference and deformation can be suppressed.
By providing the air jacket 6 around the outer cylinder 2 and providing the vacuum heat insulating layer 7 outside the air jacket 6 in this manner, the heat exchanger 1 with little heat loss to the outside can be formed. Further, a heat insulating material is not required, and the production cost can be reduced. Note that separators 4, 4 described later are provided at both ends of the outer cylinder 2 (see FIG. 3).
[0026]
The inner cylinder 5 is a hollow pipe provided at the center of the outer cylinder 2 and both ends are sealed.
Since the inner cylinder 5 is provided, the inner cylinder is hollow and lighter than a solid, so that the weight of the heat exchanger 1 can be reduced.
[0027]
As shown in FIG. 3A, a plurality of tubes 3 are provided inside the outer cylinder 2 and spirally extend radially outward from the outer periphery of the inner cylinder 5, for example, an involute as shown in FIG. It is a hollow pipe formed along a curve.
1 and 2, only one tube 3 is shown for convenience.
By providing a plurality of heat exchange tubes 3 which are respectively provided so as to form a plurality of spirals radially extending from the outer peripheral portion of the inner cylinder 5 in this manner, the radially inner tube space in the outer cylinder is provided. Since the flow path cross-sectional area and the flow path cross-sectional area of the outer tube space can be made substantially the same, each of the fluids flowing through each space is evenly distributed. As a result, the heat exchange efficiency between the fluids is improved.
In addition, in addition to the involute curve, a spiral wire (Archimedes's Any spiral curve, logarithmic spiral curve, etc.) may be used.
[0028]
As shown in FIGS. 4A and 4B, ribs 3ro and 3ri are provided on the outer surface and the outer surface of the tube 3, respectively.
As described above, when the tube 3 is provided inside the outer tube 2 on the outer surface of the tube 3, the ribs 3ro and 3ri extending in the radial direction of the outer tube 2 are provided.
(1) When the plurality of tubes 3 for heat exchange are provided inside the outer cylinder 2 and the fins 3fo are filled in the tube outer space formed by the tubes, the fins 3fo can be easily positioned.
(2) Since the flow path is narrowed by the ribs 3ro and 3ri, the pressure increases on the upstream side of the ribs 3ro and 3ri when the fluid flows through the outer space of the tube. Along the whole. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
[0029]
The fins 3fi and 3fo are provided in a space inside the tube and a space outside the tube formed by the tubes.
As the shapes of the fins 3fi and 3fo, at least one of the fins as shown in FIGS. 5A to 5F can be filled and used.
By providing the fins 3fi and 3fo in the inner space of the tube and the outer space of the tube formed by the tubes in this manner, the fluid is disturbed by the fins 3fi and 3fo, and the heat exchange efficiency between the fluids is improved. In the present embodiment, the fins 3fi and 3fo are filled in both the inner space of the tube and the outer space of the tube, but may be filled in only one of the spaces.
[0030]
Next, various fins used in the embodiment of the present invention will be briefly described with reference to FIG.
FIG. 5A shows a straight fin. The cross-sectional shape is corrugated. Has longitudinally extending peaks and valleys
FIG. 5B shows a perforated plate fin, which has a corrugated cross section, but has a plurality of holes perforated in the longitudinal direction of the corrugated plate.
FIG. 5 (c) shows a helibone fin having a wavy cross-sectional shape, but having a wavy vertical fin spine.
FIG. 5D shows a serrate fin, which has a corrugated cross-sectional shape, but has a serrated shape in the longitudinal direction in plan view.
FIG. 5E shows an offset fin in which a fluid flows through an opening of a rectangular tube sandwiched between flat plates.
FIG. 5F shows a louver fin in which folded fins are filled in compartments, and an open roof is provided at the top of each room.
Although the heat exchange efficiency between the fluids can be increased by using such fins, it is not necessary to stick to the corrugated fins, and an embossed plate may be laminated or embossed directly on the tube 3 of the present invention. The efficiency of heat exchange between fluids can also be increased by using the above. In this case, the weight can be reduced because no fin is used.
[0031]
The pipes P1 and P2 forming the fluid inlet / outlet are circular pipe members that communicate with the outer space of the tube via the bleed holes 2a and 2b.
The pipes P1 and P2 forming the inlet / outlet of the fluid may be provided so as to communicate with the space in the tube.
In the present embodiment, the pipes P1 and P2 forming the inlet / outlet of the fluid are provided so as to extend in the tangential directions opposite to each other by 180 degrees above and below the outer periphery of the air jacket 6 as shown in FIG. , P2 are respectively provided at the upper end on the other end side and the lower end on the one end side in the axial direction of the outer cylinder 2.
By providing the pipes P1 and P2 communicating with the outer space of the tube and forming the inlet and outlet of the fluid in this manner, the fluid can be smoothly introduced and discharged from the heat exchanger 1.
[0032]
As shown in FIG. 6, the separators 4, 4 are tube fixing members provided with burring holes for fitting and fixing to the outer circumferences of the tubes 3, 3,... In the radial direction of the circular plate material.
In this manner, the burring process is performed on the separators 4, 4 in the same shape as the tubes 3, 3,..., And the burring is welded to the tubes 3, 3,.
[0033]
The separators 4, 4 are provided at both ends of the outer cylinder 2, support both ends of each tube 3, and separate the space inside the tube from the space outside the tube to prevent mixing of fluid.
By providing separators 4 and 4 provided at both ends of outer cylinder 2 to support both ends of each tube 3 and to separate the inner space of the tube and the outer space of the tube and to prevent mixing of fluid, heat is provided. Not only is it easy to assemble the exchanger 1, but also the reliability of the seal structure is improved. In addition, since the number of sealing portions is small, the number of parts when assembling can be reduced. As a result, the production cost of the heat exchanger can be reduced.
In addition, flanges F1 and F2 for joining the heat exchanger 1 to other pipes are provided outside the separators 4 and 4, that is, at both ends of the heat exchanger 1.
[0034]
The flow of the fluid when the fluid A and the fluid B flow through the heat exchanger 1 of one embodiment having such a structure will be described with reference to FIG. The fluid A flows outside the tube 3 and the fluid B flows inside the tube 3.
As the flow of the fluid, the case where the inlet and outlet of the fluid flowing outside the tube 3 is on the outer periphery of the cylinder (see FIG. 7A) and the case where the inlet and outlet of the fluid flowing outside the tube 3 are on the outer periphery of the inner cylinder 5 Two (see FIG. 7B) will be described.
<When the inlet / outlet of the fluid flowing outside the tube 3 is on the outer circumference of the cylinder>
(1) The fluid A is introduced to the outside of the tubes 3 from the bleed holes 2a provided along the outer periphery of one end of the outer cylinder 2.
(2) The fluid A that has passed through the bleed holes 2a, 2a, passes through the fins 3fo, 3fo, which are filled outside the tubes 3, 3,. Are discharged to the outside through bleed holes 2b provided along the outer periphery of the portion.
(3) At this time, since the ribs 3ro and 3ri are provided on the front and back surfaces, which are the outer surfaces of the respective tubes 3, the flow paths are narrowed, and the pressure increases on the upstream side of the ribs 3ro and 3ri. The fluid A spreads over the entire outer surface of the tube 3 by the force of the pressure. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
(4) The fluid A whose flow path is narrowed and accelerated is stirred while passing through the fins 3fo, 3fo,..., And the efficiency of heat transfer with the fluid B is improved.
(5) On the other hand, the fluid B which flows through the inside of the tubes 3, 3... And flows in the axial direction of the The heat is exchanged with the fluid A while passing through the inside of the tubes 3, 3... Through the fins 3fi, 3fi. Is discharged.
As shown in FIG. 7 (a), the method of flowing the fluid B is either a parallel flow to the fluid A flowing outside the tubes 3, 3,. But you can let it flow.
[0035]
<When the inlet / outlet of the fluid flowing outside the tube is on the outer circumference of the inner cylinder>
(1) Outside the tubes 3 ', 3' ... from the bleed holes 2'a, 2'a provided along the outer circumference of one end of the inner cylinder 5 'provided at the center of the outer cylinder 2'. Fluid A is introduced.
(2) The fluid A that has passed through the bleed holes 2'a, 2'a ... is filled with fins 3'fo, 3 'which are filled outside the tubes 3', 3 '... provided in the outer cylinder 2'. are discharged to the outside through bleed holes 2'b provided along the outer periphery of the other end of the inner cylinder 5 '.
(3) At this time, since the ribs 3'ro and 3'ri are provided on the front and back surfaces, which are the outer surfaces of the respective tubes 3 ', the flow paths are narrowed and the upstream of the ribs 3'ro and 3'ri. The pressure increases on the side, and the force of this pressure causes the fluid A to spread throughout the outer surface of the tube 3 '. Accordingly, in the outer space of the tube, a short-circuit flow is small, and a uniform flow can be formed over the entire radial direction of the outer cylinder 2 '. That is, the flow rate distribution in the space outside the tube can be made uniform.
(4) The fluid A whose flow path is narrowed and accelerated is stirred while passing through the fins 3'fo, 3'fo..., And the efficiency of heat transfer with the fluid B is improved.
(5) On the other hand, the fluid B flowing through the tubes 3 ', 3'... And flowing in the axial direction of the outer cylinder 2 'flows into the outer cylinder 2' from the other end of the outer cylinder 2 '. The fluid A and the heat are passed through the fins 3'fi, 3'fi ... which are introduced inside the tubes 3 ', 3' ... provided and pass through the inside of the tubes 3 ', 3' .... It is exchanged and discharged from one end of the outer cylinder 2 'to the outside.
As shown in FIG. 7 (b), the flow of the fluid B can be either parallel flow or counter flow as described above for the fluid A flowing outside the tubes 3 ', 3'. It can also be passed by the method described above.
[0036]
As described above, in the heat exchanger according to the present invention, the inlet / outlet of the fluid flowing outside the tube can be provided at any of the outer peripheral portion of the outer cylinder and the outer peripheral portion of the inner cylinder, so that the layout property is improved. be able to.
In general, in the heat exchanger, the temperature in the axial direction fluctuates regardless of the flow type. However, if such a flow of fluid is formed in the heat exchanger and the water equivalent ratio of fluid A and fluid B is increased, as shown in FIG. The surface temperature distribution can be made uniform, and the temperature change in the axial direction can be suppressed.
[0037]
Next, a description will be given of a heat exchange reactor according to an embodiment formed by utilizing the merits of the heat exchanger according to the embodiment having such a configuration and operation. Note that the difference between the configuration of the heat exchange reactor according to the present invention and the configuration of the heat exchanger according to the present invention is that, in the heat exchange reactor according to the present invention, a metal honeycomb member ( Hereinafter, simply referred to as “metal honeycomb”), and the only difference is that a catalyst is supported on the surface of the metal honeycomb. Therefore, the same members as those of the heat exchanger of one embodiment are denoted by the same reference numerals and described. .
The heat exchange reactor according to the present invention is an external heat exchange reactor in terms of the type of the reactor.
[0038]
In the heat exchange reactor of one embodiment according to the present invention, a metal honeycomb is used instead of the fins 3fi of the heat exchanger shown in FIG. 3, and the surface of the metal honeycomb is filled with a catalyst supported. .
By filling the inside of the tube with the metal honeycomb supporting the catalyst in this way, the flow velocity of the fluid flowing through the metal honeycomb can be faster than when the fins are provided, and the surface area per volume is increased. Therefore, a cylindrical heat exchange reactor having high heat exchange efficiency between fluids and a large catalyst carrying area can be formed.
This heat exchange reactor is
(1) Compared to a square heat exchange reactor, because it has a cylindrical shape and the external surface area exposed to the outside with respect to the inner volume of the heat exchange reactor can be made smaller than that of a square heat exchange reactor. Heat loss can be reduced.
(2) Since the outer cylinder 2 has a cylindrical shape, the stress generated by the internal pressure can be dispersed uniformly, so that the pressure resistance is higher than that of a square heat exchange type reactor.
(3) Since the outer cylinder 2 is formed in a cylindrical shape, there are no portions in which the fluid does not easily flow at the four corners as in a square heat exchange reactor. Therefore, since the fluid and the catalyst are in sufficient contact, the performance of the catalyst can be improved as compared with a square heat exchange reactor.
The metal honeycomb supporting the catalyst may be provided in the outer space of the tube.
[0039]
An air jacket 6 is provided outside the outer cylinder 2, and a vacuum heat insulating layer 7 is further provided outside the air jacket 6 (see FIG. 7A).
The vacuum heat-insulating layer 7 forms two rooms partitioned outside the air jacket 6, and can be manufactured by using a vacuum in a vacuum furnace when brazing members. Further, since the vacuum heat insulating layer 7 is formed in a cylindrical shape, there is an advantage that stress due to vacuum is uniformly distributed over the entire circumference and deformation can be suppressed.
By providing the air jacket 6 around the outer cylinder 2 and providing the vacuum heat insulating layer 7 outside the air jacket 6 in this manner, a heat exchange reactor with less heat loss from the inside of the outer cylinder 2 to the outside is provided. Can be formed. Further, a heat insulating material is not required, and the production cost can be reduced.
[0040]
Further, ribs 3ri and 3ro extending in the radial direction of the outer cylinder 2 when the tube 3 is provided inside the outer cylinder 2 are provided on the outer surface of the tube 3 of the heat exchange reactor. .
As described above, when the tube is provided inside the outer cylinder 2 on the outer surface of the tube 3, the rib extending in the radial direction of the outer cylinder 2 is provided.
(1) When a plurality of tubes 3 for heat exchange are provided inside the outer cylinder 2 and the fins 3fo, 3fo... Are filled in the tube outer space formed by the tubes, the positioning of the fins 3fo, 3fo. Can be done.
(2) Since the flow path is narrowed by the ribs 3ri and 3ro, the pressure increases on the upstream side of the ribs 3ri and 3ro when the fluid flows into the outer space of the tube. Along the whole. Therefore, in the outer space of the tube, a short-circuit flow is small and a uniform flow can be formed over the entire radial direction of the outer cylinder 2. That is, the flow rate distribution in the space outside the tube can be made uniform.
[0041]
Incidentally, when actually using the heat exchange reactor of such an embodiment for the reaction,
(1) If a fluid having a large heat capacity (for example, hot water, oil, molten salts, dowsum, etc.) is allowed to flow outside the tube 3, a reaction involving intense heat of reaction (such as an oxidation reaction of carbon monoxide or an oxidation reaction of naphthalene) will occur. Reaction heat can be suitably removed.
(2) In addition, even if the reaction involves intense heat of reaction, the reaction is performed by distributing the fluid to the plurality of tubes 3, so that the reaction temperature can be easily controlled.
[0042]
Next, with reference to FIG. 9, an example in which the heat exchange reactor of one embodiment described above is used as a reforming reactor for actually performing steam reforming, for example, a steam reformer for a fuel cell. Will be explained.
The reforming raw fuel used in this embodiment refers to a hydrogen-containing organic compound which is a hydrogen-containing organic compound and can produce a hydrogen-rich gas when reformed. Further, the reformed raw fuel may be one obtained by vaporizing a mixture of the hydrogen-containing organic compound and water.
[0043]
As shown in FIG. 9, the reforming reactor 1 "" has an inner cylinder 5 "" filled with a cylindrical monolith 5 "" a as a combustion catalyst. As the combustible gas combusted by the cylindrical monolith 5 '''a, an off-gas (a mixed gas of hydrogen and air containing water) discharged from a fuel cell (not shown) is used.
By bringing the off-gas from the fuel cell into contact with the cylindrical monolith 5 '''a, a combustion gas as a heat medium is generated.
At this time, since the off-gas of the fuel cell contains a lot of water, the generated combustion gas contains a lot of water vapor. Therefore, combustion gas having a large amount of retained heat including latent heat of water can be obtained.
[0044]
The generated combustion gas fills the fins 3 "" fo, 3 "" fo ... through bleed holes 2 "" b, 2 "" b provided on the outer periphery of the other end of the inner cylinder 5 "". Is introduced into the outer space of the tube. The combustion gas introduced into the outer space of the tube is evenly distributed in the radial direction of the outer cylinder 2 ′ ″, and is agitated by the fins 3 ″ ″ fo, 3 ″ ″ fo. After radially spreading by the above, the reformed raw fuel passing through the inner space of the tube is heated and heated, and then discharged to the outside through a bleed hole 2 "" a provided on the outer periphery of one end of the outer cylinder 2 "". Is done.
Although only the upper half of the gas flow is shown in FIG. 9, the gas flows in the lower half similarly to the upper half so as to be symmetric with respect to the axis of the inner cylinder.
[0045]
On the other hand, the space inside the tube is filled with metal honeycombs 3 "" fi, 3 "" fi... As the metal component of the catalyst supported on the metal honeycombs 3 '''' fi, 3 '''' fi, at least one of platinum, rhodium, nickel and cobalt is used.
When the reformed raw fuel is passed through the metal honeycombs 3 "" fi, 3 "" fi,..., The reformed raw fuel heated to the combustion gas becomes a metal honeycomb 3 "" fi, The reformed gas is generated while being in contact with the 3 ′ ″ fi... To generate a reformed gas (hydrogen-rich gas), which is sent from the reforming reactor to a post-treatment step.
[0046]
As described above, the cylindrical monolith 5 ′ ″ a (combustion catalyst) is provided inside the inner cylinder 5 ′ ″ as a combustion gas by catalytically burning off-gas of the fuel cell, and the cylindrical monolith 5 ′ ″ a is used as the combustion catalyst. The generated combustion gas is supplied to the outer space of the tube where the metal honeycomb is not provided, and the reformed raw fuel is supplied to the inner space of the tube where the metal honeycomb is provided, so that the heat from the combustion gas is supplied. By reforming the reformed raw fuel by using the above, the combustion gas and the reformed raw fuel are each evenly distributed, and the heat exchange efficiency between the combustion gas and the reformed raw fuel is increased. A reforming reactor can be formed.
[0047]
【The invention's effect】
As described in detail in the above embodiment, the present invention has the following effects.
1. According to the first aspect of the present invention,
(1) By making the outer cylinder cylindrical, the stress generated by the internal pressure can be dispersed uniformly, so that the pressure resistance is improved as compared with the square shape. Further, since the outer cylinder has a cylindrical shape, and the outer surface area exposed to the outside with respect to the internal volume of the heat exchanger can be made smaller than that of the square shape, heat loss can be reduced as compared with the square shape.
(2) Since the inner cylinder is hollow and lighter than a solid, the weight of the heat exchanger can be reduced.
(3) By providing a plurality of tubes for heat exchange, each of which is arranged so as to form a plurality of spirals extending radially from the outer peripheral portion of the inner tube, the flow of the tube space in the radial direction in the outer tube is provided. Since the cross-sectional area of the passage and the cross-sectional area of the flow passage of the outer tube space can be made substantially the same, the fluid flowing through each space is evenly distributed. As a result, the heat exchange efficiency between the fluids is improved.
(4) By providing separators provided at both ends of the outer cylinder to support both ends of each of the tubes and partition a space inside the tube and a space outside the tube to prevent mixing of fluids, Not only is it easy to assemble, but also the reliability of the seal structure is improved. In addition, since the number of sealing portions is small, the number of parts when assembling can be reduced. As a result, manufacturing costs can be reduced.
(5) By providing the fins in the space inside the tube and / or the space outside the tube, the fluid is disturbed by the fins, and the heat exchange efficiency between the fluids is improved.
(6) By providing a pipe that communicates with either the inner space of the tube or the outer space of the tube and forms an inlet / outlet for the fluid, the fluid can be smoothly introduced and discharged to and from the heat exchanger.
2. According to the second aspect of the present invention, by providing the vacuum heat insulating layer around the outer cylinder, it is possible to form a heat exchanger with less heat loss from the inside of the outer cylinder to the outside. Further, a heat insulating material is not required, and the production cost can be reduced.
3. According to the invention as set forth in claim 3, when the tube is provided inside the outer tube on the outer surface of the tube, a rib extending in the radial direction of the outer tube is provided.
(1) When a plurality of tubes for heat exchange are provided inside the outer cylinder and the fins are filled in the tube outer space formed by the tubes, the fins can be easily positioned.
(2) Since the flow path is narrowed by the rib, when the fluid flows through the outer space of the tube, the pressure increases on the upstream side of the rib, and the fluid spreads along the outer surface of the tube by the force of this pressure. become. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
4. According to a fourth aspect of the present invention, there is provided a heat exchange reactor including the heat exchanger according to any one of the first to third aspects, wherein a metal honeycomb is used instead of the fin. Is provided, and the catalyst is carried on the surface of the metal honeycomb. As a result, the flow rate of the fluid flowing through the metal honeycomb can be increased, and the surface area per volume can be increased. And a cylindrical heat-exchange reactor having a large catalyst-supporting area.
This heat exchange reactor is
(1) Compared to a square heat exchange reactor, because it has a cylindrical shape and the external surface area exposed to the outside with respect to the internal volume of the heat exchange reactor can be made smaller than that of a square heat exchange reactor. Heat loss can be reduced.
(2) Since the outer cylinder is formed in a cylindrical shape, the stress generated by the internal pressure can be dispersed uniformly, so that the pressure resistance is higher than that of a square heat exchange type reactor.
(3) Since the outer cylinder is formed in a cylindrical shape, there are no portions in which the fluid does not easily flow at the four corners as in a square heat exchange reactor. Therefore, since the fluid and the catalyst are in sufficient contact, the performance of the catalyst can be improved as compared with a square heat exchange reactor.
5. According to the fifth aspect of the present invention, by providing the vacuum heat insulating layer around the outer cylinder, it is possible to form a heat exchange reactor with less heat loss from the inside of the outer cylinder to the outside. Further, a heat insulating material is not required, and the production cost can be reduced.
6. According to the invention as set forth in claim 6, when the tube is provided inside the outer tube on the outer surface of the tube, a rib extending in the radial direction of the outer tube is provided. Positioning when inserting the metal honeycomb into the space is facilitated. Also, since the flow path is narrowed by the rib, when the fluid flows into the outer space of the tube, the pressure increases on the upstream side of the rib, and the force of this pressure causes the fluid to spread over the entire outer surface of the tube. Become. Therefore, a short-circuit flow is small in the space outside the tube, and a uniform flow can be formed over the entire radial direction of the outer cylinder. That is, the flow rate distribution in the space outside the tube can be made uniform.
7. According to the invention as set forth in claim 7, a combustion catalyst is provided inside the inner cylinder as a heat medium by catalytically combusting a combustible gas, and the heat medium generated by the combustion catalyst is provided on the metal honeycomb. Not supplied to the inner tube space or the outer tube space, and the reformed raw fuel is supplied to the inner tube space or the outer tube space provided with the metal honeycomb, and heat from the heat medium is used. By reforming the reformed raw fuel in this manner, the heat medium and the reformed raw fuel are evenly distributed, and the heat exchange efficiency between the heat medium and the reformed raw fuel is increased. A high reforming reactor can be formed.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram showing one embodiment of a heat exchanger according to the present invention.
FIG. 2 is an external perspective view of a heat exchanger according to the present invention around an outer cylinder.
FIG. 3 (a) is a left side view of FIG.
(B) It is AA sectional drawing of FIG.3 (a).
FIG. 4A is a view for explaining the shape of a tube according to the present invention.
(B) It is a three-dimensional view of a tube.
FIG. 5 is an outline view of various fins according to the present invention.
FIG. 6 is a partial cross-sectional view illustrating a structure of a connecting portion between a tube and a separator.
FIG. 7A is a diagram for explaining a gas flow in a heat exchanger in a case where an inlet / outlet of a fluid flowing outside a tube is on an outer peripheral portion of an outer cylinder. (B) It is a figure for explaining the flow of gas in a heat exchanger when the entrance and exit of the fluid which flows outside the tube are at the perimeter of the inner cylinder.
FIG. 8 is a diagram for explaining a surface temperature distribution of a tube according to the heat exchanger of the present invention.
FIG. 9 is a diagram for explaining an example in which the heat exchange reactor according to the present invention is used as a reforming reactor.
FIG. 10A is a diagram showing a conventional regenerative heat exchanger for a gas turbine.
(B) It is a figure which shows the conventional heat exchange type reactor.
[Explanation of symbols]
1 heat exchanger
2 outer cylinder
2a, 2b Bleed hole
3 tubes
3fi fin (in tube)
3fo fin (outside the tube)
3ri, 3ro rib
4 separator
5 Inner cylinder
6 air jacket
7 Vacuum insulation layer
P1, P2 piping
F1, F2 flange

Claims (7)

A cylindrical outer cylinder,
An inner cylinder provided at the center of the outer cylinder,
A plurality of tubes for heat exchange, which are provided inside the outer cylinder and are respectively disposed so as to be a plurality of spirals extending radially from the outer peripheral portion of the inner cylinder,
A separator is provided at both ends of the outer cylinder, supports both ends of each tube, and separates the inside space of the tube and the outside space of the tube to prevent mixing of fluid,
A fin provided in the inner space of the tube and / or the outer space of the tube;
A pipe that communicates with either the inner tube space or the outer tube space to form an inlet / outlet for a fluid,
A heat exchanger, wherein fluid is passed through each of the inner space of the tube and the outer space of the tube to exchange heat. The heat exchanger according to claim 1, wherein a vacuum heat insulating layer is provided around the outer cylinder. 3. The outer surface of the tube is provided with a rib extending in a radial direction of the outer cylinder when the tube is provided inside the outer cylinder. Heat exchanger. A heat exchange reactor comprising the heat exchanger according to any one of claims 1 to 3, wherein a metal honeycomb is provided instead of the fin, and a catalyst is provided on a surface of the metal honeycomb. A heat-exchange type reactor characterized by carrying the following. The heat exchange reactor according to claim 4, wherein a vacuum heat insulating layer is provided around the outer cylinder. 6. The outer surface of the tube is provided with a rib extending in a radial direction of the outer tube when the tube is provided inside the outer tube. Heat exchange reactor. A combustion catalyst that uses a combustible gas as a heat medium by catalytically combusting a combustible gas is provided inside the inner cylinder, and the heat medium generated by the combustion catalyst is used in the inner tube space or the outer tube space where the metal honeycomb is not provided. Supplying the reformed raw fuel to the inner tube space or the outer tube space provided with the metal honeycomb, and reforming the reformed raw fuel using heat from the heat medium. A reforming reactor using the heat exchange reactor according to any one of claims 4 to 6.

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