JPWO2016139711A1 - Heat exchange device, fuel gas generator - Google Patents

Abstract

A first pipe through which the slurry body moves so that heat exchange is performed with an external fluid, and the downstream end of the first pipe is attached to the inner wall of the first pipe. The shape is such that the amount of the slurry body is less than a predetermined amount.

Description

  The present invention relates to a heat exchange device and a fuel gas generation device.

  For example, a heat exchange device having a pipe through which a slurry body moves so that heat exchange with an external fluid is performed is known (for example, Patent Document 1).

JP 2007-269945 A

  For example, in the heat exchange device of Patent Document 1, when the amount of the slurry body adhering to the inner wall of the pipe increases, the pipe is blocked and heat exchange between the slurry body and the external fluid is difficult to be performed. There is a fear.

  The main present invention that solves the above-described problem includes a first pipe through which a slurry body moves so that heat exchange is performed with an external fluid, and the downstream end of the first pipe is The heat exchange device is characterized in that the shape of the slurry body adhering to the inner wall of the first pipe is less than a predetermined amount.

  Other features of the present invention will become apparent from the accompanying drawings and the description of this specification.

  ADVANTAGE OF THE INVENTION According to this invention, while preventing the obstruction | occlusion trouble in heat exchanger outlet piping, the heat passage rate by a heat exchanger can be improved.

It is a block diagram which shows the supercritical gasification apparatus in embodiment of this invention. It is a perspective view which shows the heat exchanger in embodiment of this invention. It is a top view which shows the heat exchanger in embodiment of this invention. It is a section perspective view showing a double pipe in an embodiment of the present invention. It is a side view which shows other piping. It is a side view showing piping in an embodiment of the present invention.

At least the following matters will become apparent from the description of this specification and the accompanying drawings.
=== Supercritical gasifier ===
Hereinafter, the supercritical gasifier in the present embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing a supercritical gasifier in the present embodiment.

  The supercritical gasifier 100 (fuel gas generator) is a device that generates fuel gas from a gasification raw material or the like. The supercritical gasifier 100 includes a raw material adjustment unit 10, a raw material supply unit 20, a heat exchange unit 30, a gasification processing unit 40, and a fuel generation unit 50.

  The raw material adjusting unit 10 is a part that adjusts a raw material slurry (also referred to as “slurry body” or “raw material”) from a gasified raw material or the like, and includes an adjusting tank 11 and a crusher 12.

  The adjustment tank 11 is a container for preparing a suspension by mixing gasification raw materials, activated carbon, water, and the like, and is provided with a stirring blade (not shown). As the gasification raw material, for example, shochu residue, egg-collected chicken manure, and sludge can be used. Activated carbon functions as a nonmetallic catalyst, and porous particles having an average particle diameter of 200 μm or less can be used.

  The crusher 12 is an apparatus for crushing the solid content (mainly gasification raw material) contained in the suspension mixed in the adjustment tank 11 to make it uniform. In this embodiment, crushing is performed so that the average particle size of the solid content is 500 μm or less. Due to crushing by the crusher 12, the suspension becomes a raw slurry.

  The raw material supply unit 20 is a part that feeds the raw material slurry at a high pressure, and includes a supply pump 21 and a high pressure pump 22. The supply pump 21 is a device for supplying the raw slurry sent from the crusher 12 toward the high-pressure pump 22. The high-pressure pump 22 is a device for sending the raw slurry at high pressure. The high-pressure pump 22 pressurizes the raw material slurry to about 0.1 to 4 MPa.

  The heat exchange unit 30 heats the raw material slurry by causing heat exchange between the raw material slurry supplied from the raw material supply unit 20 and the processed fluid after being decomposed by the gasification processing unit 40. At the same time, it is a part that cools the processed fluid. The heat exchange unit 30 includes a heat exchanger 6 (heat exchange device) and a cooler 32.

  The heat exchanger 6 is a device that exchanges heat between the raw slurry and the treated fluid, and a double tube type is used. The inner channel is used as a low temperature side channel through which the raw material slurry flows, and the outer channel is used as a high temperature side channel through which the treated fluid flows. In this embodiment, the introduction temperature of the treated fluid is about 600 ° C., and the discharge temperature is about 120 ° C. On the other hand, the introduction temperature of the raw slurry is normal temperature and the discharge temperature is about 450 ° C. The heat exchanger 6 will be described later. The cooler 33 is a device that cools the processed fluid discharged from the heat exchanger 6.

  The gasification processing unit 40 is a part that heats the raw material slurry heated by the heat exchanger 6 to a supercritical state and decomposes organic substances contained in the raw material slurry, and has a preheater 41 and a gasification reactor 42. ing. The preheater 41 is a device for preheating the raw material slurry discharged from the heat exchanger 6, and in this embodiment, the raw material slurry introduced at about 450 ° C is heated to about 600 ° C. The gasification reactor 42 is an apparatus for decomposing organic substances contained in the raw material slurry while maintaining the raw material slurry in a supercritical state. In this embodiment, the temperature is set to 600 ° C., the pressure is set to 25 MPa, and the raw material slurry is decomposed for 1 to 2 minutes.

  The fuel generator 50 generates fuel gas from the processed fluid. The fuel generator 50 includes a decompressor 51, a gas-liquid separator 51, a catalyst recovery unit, and a gas tank 54.

The decompressor 51 decompresses the processed fluid cooled by the cooler 32. The gas-liquid separator 52 separates the processed fluid decompressed by the decompressor 51 into a gas (fuel gas) and a liquid (drainage, activated carbon, ash). Then, the separated liquid is discharged via the catalyst recovery unit 53. On the other hand, the separated gas is stored in the gas tank 54.
=== Heat exchanger ===
Hereinafter, with reference to FIG. 2 thru | or FIG. 4, the heat exchanger in this embodiment is demonstrated. FIG. 2 is a perspective view showing a heat exchanger in the present embodiment. FIG. 3 is a plan view showing the heat exchanger in the present embodiment. FIG. 4 is a cross-sectional perspective view showing the double tube in the present embodiment. FIG. 4 shows the double pipe 61 in a state viewed from a cross section substantially orthogonal to the longitudinal direction of the double pipe 61. A part of the inner tube 612 is indicated by a broken line for convenience of explanation.

  The heat exchanger 6 is a device that exchanges heat between the slurry body and the processed fluid. The processed fluid is a slurry body processed by the gasification processing unit 40.

  The heat exchanger 6 has a double pipe 61 and pipes 62 to 65.

  The double pipe 61 has an outer pipe 611 and an inner pipe 612. The inner pipe 612 is, for example, a metal pipe through which the slurry body moves. The inner tube 612 is inserted into the outer tube 611 so that a gap for moving the processed fluid is formed between the inner tube 612 and the outer tube 611. The inner side of the inner pipe 612 corresponds to the inner flow path, and the gap between the inner pipe 612 and the outer pipe 611 corresponds to the outer flow path. The outer tube 611 is, for example, a metal pipe through which the inner tube 612 is inserted.

  The double pipe 61 is centered on a winding axis (not shown) along the vertical direction (Z axis) so that the length of the double pipe 61 can be relatively long in a relatively narrow space. It is wound in a spiral. That is, the outer tube 611 and the inner tube 612 are both spirally wound.

  The pipes 62 and 63 are coupled to one end of the double pipe 61 via a coupling portion P2 provided on the upper side (+ Z) from the coupling portion P1. The pipe 62 is coupled so as to communicate with the inner flow path. The pipe 63 is coupled so as to communicate with the outer flow path. The inner pipe 612 and the pipe 62 correspond to the first pipe. The outer pipe 611 corresponds to the second pipe.

  The pipes 64 and 65 are coupled to the other end of the double pipe 61 through a coupling part P1 provided on the lower side (−Z) than the coupling part P2. The pipe 65 is coupled so as to communicate with the inner flow path. The pipe 64 is coupled so as to communicate with the outer flow path.

A slurry body is supplied to the pipe 65 from the raw material supply unit 20. This slurry body is supplied to the gasification processing unit 40 via the inner flow path of the double pipe 61 and the pipe 62. Further, the post-treatment fluid is supplied to the pipe 63 from the gasification processing unit 40. The post-treatment fluid is supplied to the cooler 32 via the outer flow path of the double pipe 61 and the pipe 64. That is, in the double pipe 61, the flow direction of the slurry body and the flow direction of the processed fluid are opposed to each other.
=== Radius of curvature of piping ===
Hereinafter, the curvature radius of the piping in the present embodiment will be described with reference to FIGS. 5 and 6. FIG. 5 is a side view showing another pipe. FIG. 6 is a side view showing the piping in the present embodiment. FIG. 6 shows the pipe 62 in a state where the product T1 in FIG. 5 flows toward the downstream side without adhering to the inner wall.
= Other piping, products =
The other pipe 620 is another heat exchanger pipe having the same configuration as the pipe 62 of the heat exchanger 6. The radius of curvature of the bent portion 62B of the other pipe 620 is smaller than the radius of curvature of the pipe 62, and is set to about 38 (mm), for example. The configuration of the other heat exchangers other than the other pipes 620 is the same as the configuration of the heat exchanger 6.

  For example, the product T1 (slurry body) may adhere to the bent portion 62B of the other pipe 620 and the inner wall near the bent portion 62B on the downstream side of the bent portion 62B. This is based on, for example, the change in the moving direction and moving speed of the slurry body in the bent portion 62B. For example, the slurry body comes into contact with the inner wall of the pipe at a position where the moving direction of the slurry body changes suddenly, but the position is also a position where the moving speed is reduced, so that the product T1 adheres and is easily laminated. The product T1 is, for example, tar and char generated when the slurry body is heated.

  When the amount of the product T1 attached to the inner wall of the other pipe 620 increases, for example, the movement of the slurry body may be hindered by the attached product T1. In this case, since the movement of the slurry body is hindered in the other heat exchanger, the moving speed of the slurry body is reduced and the slurry body adheres to the inner wall of the other heat exchanger, and the slurry body in the other heat exchanger The heat transfer rate with the fluid after treatment may be reduced. When the amount of the product T1 adhering to the inner wall of the other pipe 620 further increases, for example, the other pipe 620 may be blocked. In this case, it may be difficult for another supercritical gasifier having another heat exchanger to generate the fuel gas.

Therefore, in the heat exchanger 6, the amount of the product T1 adhering to the inner wall of the pipe 62 needs to be smaller than a predetermined amount. The predetermined amount may be, for example, an amount that does not block the pipe 62, and the heat exchanger 6 has a heat passage rate that allows the temperature of the slurry discharged from the pipe 62 to be about 450 ° C. It is good also as a quantity defined based on experiment or simulation whether it can be maintained in.
= Curvature radius of piping 62 =
The pipe 62 has a shape bent so that the radius of curvature of the bent portion 62A in the pipe 62 is larger than the radius of curvature of the bent portion 62B in the other pipe 620. The radius of curvature of the bending portion 62A is set to a predetermined radius of curvature based on, for example, experiments or simulations so that the amount of the product T1 adhering to the inner wall of the pipe 62 is smaller than the predetermined amount. For example, the predetermined radius of curvature may be about 200 (mm), which is the same as the radius of curvature of the bent portions 61A and 61B (FIG. 3) of the double pipe 61.
=== Operation of heat exchanger ===
Hereinafter, the operation of the heat exchanger in the present embodiment will be described with reference to FIGS. 1, 3, and 6.

  The raw material adjusting unit 10 adjusts (generates) a slurry body from a gasification raw material or the like. The raw material supply unit 20 pressurizes the slurry body adjusted by the raw material adjustment unit 10 and supplies it to the pipe 65 in the heat exchanger 6. The slurry body supplied from the raw material supply unit 20 to the pipe 65 is supplied to the gasification processing unit 40 via the inner flow path and the pipe 62. At this time, since the curvature radius of the bending portion 62A is set to a predetermined curvature radius, for example, the product T1 flows downstream, so that the amount of the product T1 adhering to the inner wall of the pipe 62 is smaller than the predetermined amount. Become. Therefore, the heat transfer rate between the slurry body and the treated fluid in the heat exchanger 6 can be improved.

  The gasification processing unit 40 heats the slurry body heated by the heat exchanger 6 and supplied to the gasification processing unit 40 to generate a post-processing fluid. The post-treatment fluid generated by the gasification processing unit 40 is supplied to the pipe 63 in the heat exchanger 6. The processed fluid supplied from the gasification processing unit 40 to the pipe 63 is supplied to the fuel generation unit 50 via the outer flow path, the pipe 64, and the cooler 32. Thereafter, the fuel generator 50 generates fuel gas from the supplied processed fluid.

  As described above, the heat exchanger 6 has the double pipe 61 and the pipe 62. In the inner pipe 612 of the double pipe 61, the slurry body moves through the inside so that heat exchange is performed with the external processed fluid. The pipe 62 is coupled to the inner pipe 612 so as to communicate with the inner pipe 612 on the downstream side of the inner pipe 612. The pipe 62 has a shape such that the amount of the product T1 adhering to the inner wall of the pipe 62 is less than a predetermined amount. Therefore, the heat passage rate of the heat exchanger 6 can be improved. Further, the pipe 62 is prevented from being blocked by the product T1, and the slurry body can be reliably supplied from the heat exchanger 6 to the gasification processing unit 40. That is, the fuel gas can be reliably generated in the supercritical gasifier 100.

  Further, the pipe 62 has a shape bent with a predetermined curvature so that the curvature radius of the bent portion 62A becomes a predetermined curvature radius. The pipe 62 is prevented from being blocked by the product T1, and the slurry body can be reliably supplied from the heat exchanger 6 to the gasification processing unit 40. Therefore, the heat passage rate of the heat exchanger 6 is improved. Can be made. Further, since the pipe 62 is bent, the heat exchanger 6 can be downsized.

  Further, the inner tube 612 is inserted into the outer tube 611 so that the fluid moves after the process through the gap between the outer tube 612 and the inner tube 612. The outer tube 611 has a shape that is spirally wound together with the inner tube 612. Therefore, the heat exchanger 6 can be further reduced in size. Further, since the length of the double pipe 61 can be made relatively long, the amount of heat exchanged in the heat exchanger 6 can be further increased.

  In addition, the slurry body is supplied to the inner pipe 612 so that the flow direction of the slurry body and the flow direction of the processed fluid are opposed to each other inside the outer pipe 611. Therefore, the temperature exchange performance of the heat exchanger 6 can be further improved.

  In addition, the said embodiment is for making an understanding of this invention easy, and is not for limiting and interpreting this invention. The present invention can be changed and improved without departing from the gist thereof, and the present invention includes equivalents thereof.

  In the present embodiment, the pipe 62 has been described as having a bent shape, but the present invention is not limited to this. For example, the pipe 62 may have a straight shape. That is, the pipe 62 may be a straight pipe. In this case, no bending portion is provided in the pipe 62, and the moving direction and moving speed of the slurry body inside the pipe 62 are substantially the same at each position in the cross section of the pipe 62. For this reason, the amount of the product T1 adhering to the inner wall of the pipe 62 becomes smaller than a predetermined amount.

  In the present embodiment, the post-processing fluid is supplied to the outer flow path of the double pipe 61. However, the present invention is not limited to this. For example, a fluid other than the post-treatment fluid may be supplied to the outer flow path of the double pipe 61. The temperature of the other fluid is set to be higher than the temperature of the slurry body supplied to the inner pipe 612.

  Moreover, although this embodiment demonstrated that the inner tube | pipe 612 was penetrated by the outer tube | pipe 611, it is not limited to this. For example, the inner pipe 612 may be provided in the storage tank. It is assumed that a fluid having a temperature higher than the temperature of the slurry supplied to the inner pipe 612 is stored in the storage tank. In this case, in the slurry body in the inner pipe 612, heat exchange is performed with the fluid stored in the storage tank.

  In the present embodiment, the slurry body is supplied from the raw material supply unit 20 to the pipe 65 and the post-treatment fluid is supplied from the gasification processing unit 40 to the pipe 63. However, the present invention is not limited to this. Absent. For example, the slurry body may be supplied to the pipe 62 from the raw material supply unit 20, and the post-treatment fluid may be supplied to the pipe 64 from the gasification processing unit 40. Further, for example, the slurry body may be supplied to the pipe 65 from the raw material supply unit 20, and the post-treatment fluid may be supplied to the pipe 64 from the gasification processing unit 40. For example, the pipe 62 may be supplied from the raw material supply unit 20. The slurry body may be supplied, and the processed fluid may be supplied from the gasification processing unit 40 to the pipe 63. In this case, in the double pipe 61, the flow direction of the slurry body and the flow direction of the processed fluid are the same direction.

  In the present embodiment, the pipes 62 and 65 communicate with the inner flow path, and the pipes 63 and 64 communicate with the outer flow path. However, the present invention is not limited to this. For example, the pipes 62 and 65 may communicate with the outer flow path, and the pipes 63 and 64 may communicate with the inner flow path. In this case, the processed fluid moves in the inner flow path, and the slurry body moves in the outer flow path.

6 Heat Exchanger 30 Heat Exchanger 61 Double Pipe 62, 63, 64, 65 Pipe 100 Supercritical Gasifier 611 Outer Pipe 612 Inner Pipe

The main present invention that solves the above-described problems is a heat exchange device used in a fuel gas generation device that heats a slurry body prepared with organic substances to a supercritical state, and performs heat exchange with an external fluid. first pipe, comprising a said slurry body is moved inside such, the downstream end outside the said first pipe is a lower temperature than the slurry body, the slurry body attached to the inner wall of the first pipe The heat exchange device is characterized in that it has a shape such that the amount of is less than a predetermined amount.

Claims (12)

A first pipe through which the slurry body moves so that heat exchange is performed with an external fluid;
The downstream end of the first pipe has a shape such that the amount of the slurry adhering to the inner wall of the first pipe is less than a predetermined amount. The heat exchange device according to claim 1, wherein the end portion has a shape bent with a predetermined curvature. The heat exchanger according to claim 1, wherein the end portion is formed of a straight pipe.   4. The apparatus according to claim 1, further comprising a second pipe through which the first pipe is inserted so that the fluid moves through a gap between the first pipe and the first pipe. 5. Heat exchange device.   4. The apparatus according to claim 1, further comprising a second pipe inserted through the first pipe so that the fluid moves through a gap between the first pipe and the first pipe. 5. Heat exchange device. The slurry body is supplied to the first pipe so that a flow direction of the slurry body and a flow direction of the fluid are opposed to each other inside the second pipe. The heat exchange apparatus as described. A heat exchange device having a first pipe through which the slurry body moves so that heat exchange for heating the slurry body as a gasification raw material is performed with an external fluid;
A fuel gas generation device comprising: a generation device that generates fuel gas from the slurry body supplied via the first pipe. The fuel gas generating device according to claim 7, wherein the end portion has a shape bent with a predetermined curvature. The fuel gas generating device according to claim 7, wherein the end portion is formed of a straight pipe.   The second pipe through which the first pipe is inserted so that the fluid moves through a gap between the first pipe and the first pipe. Fuel gas generator.   The fuel according to any one of claims 7 to 9, further comprising a second pipe that is inserted into the first pipe so that the fluid moves through a gap between the first pipe and the first pipe. Gas generator. The slurry body is supplied to the first pipe so that a flow direction of the slurry body and a flow direction of the fluid are opposed to each other inside the second pipe. The fuel gas generating device described.

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