The present invention relates to a vaporization method for vaporizing liquid while recovering power using a Stirling engine, a vaporization apparatus used for the vaporization method, and a vaporization system provided with the vaporization apparatus.
A Stirling engine has been known in the past. The Stirling engine includes a heat exchange unit for hot energy and a heat exchange unit for cold energy. Hot energy is supplied to the heat exchange unit for hot energy and cold energy is supplied to the heat exchange for cold energy, whereby the Stirling engine obtains power.
A technology is known for vaporizing liquid while recovering power by adopting cold energy (latent heat) of the liquid as the cold energy supplied to the Stirling engine of this type (e.g., Patent Document 1). In other words, the Stirling engine according to Patent Document 1 vaporizes liquid (LNG: liquefied natural gas) while recovering power by applying the heat of vaporization to the liquid.
Specifically, a Stirling engine 102 of Patent Document 1 includes, as shown in
However, in the Stirling engine 102 of Patent Document 1, complicated processing is necessary in order to obtain target gas from the liquid (LNG) at high efficiency. Specifically, the Stirling engine 102 of Patent Document 1 is configured to immerse the head of the Displacer cylinder 106 in the liquid stored in the cooler 104 in order to bring the liquid into contact with the displacer cylinder 106. Therefore, gas already vaporized and gas not vaporized yet are separated. In order to obtain target gas at high efficiency in a state in which the liquid and the gas are separated in this way, as shown in
Therefore, in order to obtain target gas at high efficiency using the Stirling engine 102 of Patent Document 1, there is a problem in that a process and equipment therefor are complicated.
Patent Document 1: Japanese Patent Application Laid-Open No. H11-22550
An object of the present invention is to provide a vaporization method that can obtain target gas at high efficiency using a Stirling engine without requiring a complicated process and complicated equipment, a vaporization apparatus used for the vaporization method, and a vaporization system provided with the vaporization apparatus.
According to an aspect of the present invention, there is provided a method of vaporizing liquid using a Stirling engine including a heat exchange unit for cold energy, the method including: a preparing step of preparing a conduit that covers at least a part of the heat exchange unit for cold energy of the Stirling engine and is capable of forming an ascending flow of the liquid flowing from a bottom to a top of the heat exchange unit for cold energy; and a vaporizing step of feeding the liquid in the conduit to thereby form the ascending flow and bringing the liquid into contact with the Stirling engine to vaporize the liquid. In the preparing step, a flowing direction of the ascending flow is adjusted to be an angle set in advance for suppressing occurrence of separated flows of the liquid and gas in the conduit. In the vaporizing step, the liquid is fed at a flow velocity at which a gas-liquid two-phase flow in which the liquid and the gas are mixed is formed in the conduit.
A preferred embodiment of the present invention is explained below with reference to the drawings.
Referring to
The Stirling engine 2 includes a heat exchange unit for cold energy 6 for cooling working gas (e.g., hydrogen gas or nitrogen gas) in a not-shown displacer cylinder and a heat exchange unit for hot energy 7 for heating the gas in the displacer cylinder, a displacer piston 8 movable in the displacer cylinder, a power piston 9 movable according to compression or expansion of the gas in the displacer cylinder, and a crankshaft 10 to which the displacer piston 8 and the power piston 9 are coupled. In the Stirling engine 2, when the gas in the displacer cylinder is cooled in the heat exchange unit for cold energy 6, the power piston 9 moves in a direction for reducing the volume of the displacer cylinder. According to the movement of the power piston 9, the displacer piston 8 moves in a direction for increasing the volume on the heat exchange unit for hot energy 7. Then, according to the increase in the gas heated by the heat exchange unit for hot energy 7, the power piston 9 moves in a direction for increasing the volume of the displacer cylinder. According to the movement, the displacer piston 8 moves in a direction for increasing the volume of the heat exchange unit for cold energy 6. This action is repeatedly performed, whereby power used for a rotating action of the crankshaft 10 can be recovered.
The heat exchange unit for cold energy 6 includes a U-shaped metal tube (an encapsulating section) 6b in which the working gas circulates and six metal plates (extending sections) 6a heat-conductibly coupled to the metal tube 6b. Each of the metal plates 6a is arranged in a standing posture. The metal plates 6a are arranged substantially in parallel to one another in a state in which the metal plates 6a are pierced through by the metal tube 6b. The metal plates 6a are arranged such that regions on one side (the upper side in
The vaporizing tube 4 is a conduit for vaporizing the LNG. When the LNG circulates inside the vaporizing tube 4 in a state in which the vaporizing tube 4 is attached to the Stirling engine 2, the LNG in the vaporizing tube 4 vaporizes with the heat of vaporization received from the heat exchange unit for cold energy 6. Specifically, the vaporizing tube 4 includes a lead-in section 11 for leading in the LNG from the pump 3, a vaporizing section (a heat exchange section or an auxiliary heat exchange section) 12 that cools the heat exchange unit for cold energy 6 of the Stirling engine 2 with the LNG from the lead-in section 11, and a lead-out section 14 for leading out the LNG from the vaporizing section 12. The lead-in section 11, the vaporizing section 12, and the lead-out section 14 are coaxially arranged along an axis in the up-down direction. Consequently, a channel in the vaporizing tube 4 has a shape for circulating liquid in a direction having an upward component in the entire range from the lead-in section 11 to the lead-out section 14. ‘The shape for circulating liquid in a direction having an upward component in the entire range from the lead-in section 11 to the lead-out section 14’ means the shape of the channel that can be arranged in a state not including a section where a position on an upstream side is higher than a position on a downstream side. This means that the shape is not limited to a linear shape and includes a curved shape.
The vaporizing section 12 houses the distal end of the metal tube 6b and the metal plates 6a. Specifically, in the vaporizing section 12, the metal plates 6a are arranged to extend along the axis of the vaporizing tube 4 in a state in which the sidewalls of the metal plates 6a are pierced through by the metal tube 6b. The vaporizing section 12 houses the metal plates 6a in a posture in which portions on one side (the upper side in
The vaporizing tube 4 according to this embodiment is attached to the Stirling engine 2 to form a vertical ascending flow F1 (see
Specifically, the vaporizing tube 4 has an inner diameter dimension set to generate an air bubble flow concerning a range E1 (see
(1) Concerning the Range E1 and the Range E2
Concerning the range E1 and the range E2, an inner diameter dimension d serving as a flow velocity parameter UL/φ2 of a liquid phase is calculated on the basis of Formula 1 below such that the fluidized state of the gas-liquid two-phase flow shown in
φ2=d/d° Formula 1
In this embodiment, the inner diameter dimension of the range E1 is set smaller than the inner diameter dimension of the range E2. As a result, the flow velocity in the range E1 increases. Consequently, the density of the liquid in the gas-liquid two-phase flow in the range E1 is equal to or higher than the density of the liquid in the gas-liquid two-phase flow in the range E2. Therefore, it is possible to keep large cold energy of the gas-fluid two-phase flow in the range E1, which is a pre-stage of the range E2, i.e., the heat exchange section. As a result, it is possible to further improve the efficiency of heat exchange.
(2) Concerning the Range E3
Concerning the range E3, the flow velocity parameter UL/φ2 of the liquid phase is calculated on the basis of Formula 1 above and a flow velocity parameter UG/φ1 of the gas phase is calculated on the basis of Formula 2 below such that the fluidized state of the gas-liquid two-phase flow generated in the range E2 is the air bubble flow, the slag flow, or the intermittent flow. The inner diameter dimension d of the range E3 is set to satisfy these conditions. The flow velocity parameter UL/φ2 of the liquid phase concerning the air bubble flow, the slag flow, or the intermittent flow is the same as Formula 1 above. UG is the flow velocity of the gas phase, φ1 is a correction coefficient set to have a value of 1 when the inner diameter of the conduit is 2.54 cm, and θ is an angle (in this embodiment, 90°) formed by the flowing direction of the LNG and the horizontal direction.
φ1=(d/d°)0.8(1−0.65 cosθ) Formula 2
(3) Concerning the Range E4
Concerning the range E4, the inner diameter dimension d is set such that the fluidized state of the gas-liquid two-phase flow generated in the range E3 is the intermittent flow or the annular flow. Specifically, when the intermittent flow is formed, the flow velocity parameter UL/φ2 of the liquid phase is calculated on the basis of Formula 1 above, the flow velocity parameter UG/φ1 of the gas phase is calculated on the basis of Formula 2 above, and the inner dimension parameter d of the range E4 is set to satisfy these conditions.
On the other hand, when the annular flow is formed, the flow velocity parameter UL/φ2 of the liquid phase is calculated, the flow velocity parameter UG/φ1 of the gas phase is calculated on the basis of Formula 3 below, and the inner dimension parameter d of the range E4 is set to satisfy these conditions. φ2 in the formation of the annular flow is 1. Therefore, a flow velocity parameter of the liquid phase depends on the flow velocity UL. ρG is the density of the gas, ρG0 is 1.3 kg×m−3, Δρ0 is (ρL0−ρG0), Δρ is (ρL−ρG), σ0 is 0.07 N×m−1, and σ is surface tension.
The operation of the vaporization system 1 is explained below.
First, as explained above, the vaporizing tube 4 that covers the heat exchange unit for cold energy 6 of the Stirling engine 2 and is capable of forming a vertical ascending flow of the liquid flowing from the bottom to the top of the heat exchange unit for cold energy 6 is prepared (a preparing step).
Subsequently, the pump 3 is provided below the vaporizing tube 4 and the vaporizing heater 5 is provided above the vaporizing tube 4. The LNG is ejected from the pump 3, whereby the vertical ascending flow F1 of the LNG led in from below (the lead-in section 11) the vaporizing tube 4 and led out from above (the lead-out section 14) the vaporizing tube 4 is formed.
Specifically, the LNG changes to an air bubble flow in the lead-in section 11 (the range E1) to be led into the vaporizing section 12. The liquid not vaporized yet in the LNG led into the vaporizing section 12 in the state of the air bubble flow comes into contact with the metal tube 6b in the range E2 and receives the heat of vaporization from the metal tube 6b to thereby vaporize (a vaporizing step). Consequently, in the range E3 located further on the downstream side than the range E2, as an air bubble flow same as that in the range E2 or a slag flow or an intermittent flow having a less liquid phase compared with the range E2 is formed. In the range E3, the liquid not vaporized yet in the gas-liquid two-phase flow led in from the range E2 comes into contact with the metal plates 6a and receives the heat of vaporization from the metal plates 6a to thereby vaporize. The gas-liquid two-phase flow from the range E3 is led out from the lead-out section 14 in a state in which the gas-liquid two-phase flow is changed to an intermittent flow or an annular flow in the range E4.
Further, in this embodiment, the vaporizing heater 5 is provided on the lead-out section 14 and the gas-liquid two-phase flow led out from the lead-out section 14 is guided to the vaporizing heater 5 in the form of the ascending flow F1 (a guiding step). Therefore, the liquid not vaporized by the heat exchange unit for cold energy 6 of the Stirling engine 2 is guided to the vaporizing heater 5 together with the liquid already vaporized and is vaporized in the vaporizing heater 5. On the other hand, the gas is heated in the vaporizing heater 5.
As explained above, according to the embodiment, since the vertical ascending flow F1 is formed, it is possible to suppress occurrence of separated flows of the liquid and the gas in the vaporizing tube 4. Therefore, even when the flow velocity of the liquid is low, it is possible to maintain the gas-liquid two-phase flow in which the gas and the liquid are mixed without a gas-liquid interface being separated. A reason for the above is explained with reference to
In the embodiment, ‘an angle set in advance for suppressing occurrence of separated flows of the liquid and gas in the conduit’ means an angle θ that satisfies the condition of Formula 4 below. θ is an angle formed by the flowing direction of the ascending flow and the horizontal direction, d is the inner diameter (the diameter) of the conduit, and 1 is a channel length of the gas-liquid two-phase flow in the conduit.
In the embodiment, the ascending flow is formed vertically. However, the ascending flow is not limited to be vertically formed. It is possible to suppress the occurrence of the separated flows if the flowing direction of the ascending flow is adjusted to be fit within a range of the angle θ of Formula 4 below.
In the embodiment, after the occurrence of the separated flows is suppressed as explained above, the liquid is supplied from the pump 3 at a flow velocity at which the gas-liquid two-phase flow is formed in the vaporizing tube 4. Therefore, it is possible to effectively vaporize the liquid contained in the gas-liquid two-phase flow with the heat of vaporization received from the heat exchange unit for cold energy 6 of the Stirling engine 2 while effectively circulating the gas-liquid two-phase flow in the state in which the gas and the liquid are mixed.
Therefore, according to the embodiment, it is possible to perform vaporization of the remaining liquid while collecting the target gas by circulating the liquid and the gas as the gas-liquid two-phase flow of the vertical ascending flow F1. Therefore, it is possible to obtain the target gas at high efficiency without requiring a complicated process and complicated equipment. In particular, when liquid in which a plurality of components having different boiling points are mixed such as the LNG is supplied to the vaporizing tube 4, low-boiling point components can be easily vaporized by the heat of vaporization from the Stirling engine 2. On the other hand, high-boiling point components may be unable to be sufficiently vaporized by the heat of vaporization from the Stirling engine 2. However, by adopting the vaporization system according to the embodiment, it is possible to effectively guide low-boiling point components (gas) already vaporized and high-boiling point components (liquid) not vaporized yet to the vaporizing heater 5. Therefore, it is possible to vaporize the high-boiling components with the vaporizing heater 5. Consequently, it is possible to obtain target natural gas at high efficiency.
The embodiment is a configuration for forming the air bubble flow in the range E2 (the heat exchange section) and forming the air bubble flow, the slag flow, or the intermittent flow in the range E3 (the auxiliary heat exchange section). With this configuration, it is possible to circulate the liquid at a relatively low velocity and uniformly. Therefore, it is possible to surely bring the liquid and the heat exchange unit for cold energy 6 into contact with each other. Consequently, it is possible to realize efficiency of vaporization.
The embodiment is a configuration in which the inner diameter dimension of the lead-in section 11 is set smaller than the inner diameter dimension of the vaporizing section 12. With this configuration, it is possible to set the density of the liquid in the lead-in section 11 larger than the density of the liquid in the vaporizing section 12. Therefore, it is possible to maintain a state in which a lot of cold energy is retained at a stage before the liquid is guided to the vaporizing section 12. As a result, it is possible to more effectively perform vaporization in the vaporizing section 12.
In the embodiment, the heat exchange unit for cold energy 6 includes the metal tube (the encapsulating section) 6b and the plurality of metal plates (the extending sections) 6a. The gas-liquid two-phase flow is formed in the range E2 (the heat exchanging section) and the range E3 (the auxiliary heat exchanging section). With this form, it is possible to effectively vaporize the liquid in the range E3 in addition to the range E2.
If the liquid and the gas are led from the lead-out section 14 to the vaporizing heater 5 while being kept in the state of the ascending flow F1 as in the embodiment, it is possible to suppress the occurrence of the separate flows between the lead-out section 14 and the vaporizing heater 5 as well. Therefore, it is possible to vaporize the liquid, which is not vaporized by the Stirling engine 2, with the vaporizing heater 5 and obtain the target gas at high efficiency.
In the embodiment, the vaporizing tube 4 including the linear channel in which the lead-in section 11, the vaporizing section 12, and the lead-out section 14 are coaxially arranged is explained. However, the channel in the vaporizing tube 4 is not limited to the linear shape and may be, for example, a curved shape as long as the shape is the shape of the channel that can be arranged in a state in which the channel does not have a section where the position on the upstream side of the channel is higher than the position on the downstream side.
In the embodiment, the cylindrical vaporizing tube 4 is explained. However, the sectional shape of the vaporizing tube is not limited to a circle and may be, for example, a rectangle as shown in
The diameter dimension of the vaporizing tube 4 in the case in which LNG having 0.3 MPaG and −160° C. is supplied at a flow rate of 1 t/h is explained below. It is assumed that the LNG supplied to the vaporizing tube 4 is heated to −133° C. by heat exchange with the heat exchange unit for cold energy 6 of the Stirling engine 2.
(1) Concerning the Range E1 (see
In this example, an air bubble flow is generated concerning the range E1. Therefore, a value of the flow velocity parameter UL/φ2 is required to be smaller than 3 (see
It is examined whether the condition is satisfied. The density of the LNG at 0.3 MPaG and −160° C. is 460 kg/m3. Therefore, the flow rate of the LNG in the range E1 is 0.604×10−3 m3/sec. Since the diameter dimension d of the range E1 is 40 mm, the flow velocity UL is about 0.5 m/sec. Therefore, when the diameter dimension of the range E1 is set to 40 mm, the condition (the flow velocity UL<4.724 m/sec) is satisfied.
(2) Concerning the Range E2 (see
In this example, an air bubble flow is generated concerning the range E2. Therefore, a value of the flow velocity parameter UL/φ2 is required to be smaller than 3 (see
It is examined whether the condition is satisfied. The density of the LNG at 0.3 MPaG and −160° C. is 460 kg/m3. Therefore, the flow rate of the LNG in the range E2 is 0.604×10−3 m3/sec. Since the diameter dimension d of the range E2 is 500 mm, the flow velocity UL is about 3.1×10−3 m/sec. Therefore, when the diameter dimension of the range E2 is set to 500 mm, the condition (the flow velocity UL<59.06 m/sec) is satisfied.
(3) Concerning the Range E3 (see
In this example, an air bubble flow, a slag flow, or an intermittent flow is generated concerning the range E3. Therefore, a value of the flow velocity parameter UG/φ1 is required to be smaller than 1.0 (see
It is examined whether the condition is satisfied. From a relation with the density of the LNG at 0.3 MPaG and −133° C., the flow rate of the LNG in the range E3 is 0.058 m3/sec. Since the diameter dimension d of the range E3 is 500 mm, the flow velocity UG is about 0.3 m/sec.
(4) Concerning the Range E4 (see
In this example, a slag flow, an intermittent flow, or an annular flow is generated concerning the range E4. Therefore, a value of the flow velocity parameter UG/φ1 is required to be larger than 0.1 (
It is examined whether the condition is satisfied. From a relation with the density of the LNG at 0.3 MPaG and −133° C., the flow rate of the LNG in the range E4 is 0.058 m3/sec. Since the diameter dimension d of the range E4 is 120 mm, the flow velocity UG is about 5 m3/sec. Therefore, when the diameter dimension of the range E4 is set to 120 mm, the condition (the flow velocity UG>0.346 m/sec) is satisfied.
The embodiment explained above is summarized as explained below.
A vaporization method according to the embodiment is a method of vaporizing liquid using a Stirling engine including a heat exchange unit for cold energy, the method including: a preparing step of preparing a conduit that covers at least a part of the heat exchange unit for cold energy of the Stirling engine and is capable of forming an ascending flow of the liquid flowing from a bottom to a top of the heat exchange unit for cold energy; and a vaporizing step of feeding the liquid in the conduit to thereby form the ascending flow and bringing the liquid into contact with the Stirling engine to vaporize the liquid. In the preparing step, a flowing direction of the ascending flow is adjusted to be an angle set in advance for suppressing occurrence of separated flows of the liquid and gas in the conduit. In the vaporizing step, the liquid is fed at a flow velocity at which a gas-liquid two-phase flow in which the liquid and the gas are mixed is formed in the conduit.
With this configuration, since the flowing direction of the ascending flow is adjusted to the predetermined angle, it is possible to suppress the occurrence of the separated flows of the liquid and the gas in the conduit. Therefore, even when the flow velocity of the liquid is low, it is possible to maintain the gas-liquid two-phase flow in which the gas and the liquid are mixed without a gas-liquid interface being separated.
In the vaporizing step, the liquid is fed at a flow velocity at which an intermittent flow or an air bubble flow is formed in a heat exchange section of the conduit in which the heat exchange unit for cold energy and the liquid come into contact with each other.
With this configuration, it is possible to more effectively bring the liquid and the heat exchange unit for cold energy into contact with each other.
In the preparing step, the conduit is prepared including a heat exchange section in which the heat exchange unit for cold energy and the liquid come into contact with each other, and a lead-in section that has a sectional area smaller than a sectional area of a channel of the heat exchange section and that leads the liquid into the heat exchange section.
With this configuration, since the sectional area of the channel in the lead-in section is set smaller than the sectional area of the channel in the heat exchange section, it is possible to set the density of the liquid in the lead-in section larger than the density of the liquid in the heat exchange section. Therefore, it is possible to maintain a state in which a lot of cold energy is retained at a stage before the liquid is guided to the heat exchange section. As a result, it is possible to more effectively perform vaporization in the heat exchange section.
The heat exchange unit for cold energy includes an encapsulating section in which working gas of the Stirling engine is encapsulated, and a plurality of extending sections heat-conductibly coupled to the encapsulating section and extending in a flowing direction of the liquid from the encapsulating section. In the preparing step, the conduit is prepared including a heat exchange section which covers at least a part of the encapsulating section and in which the encapsulating section and the liquid come into contact with each other, and an auxiliary heat exchange section which covers the extending sections and in which the extending sections and the liquid come into contact with each other. In the vaporizing step, the liquid is fed at a flow velocity at which the gas-liquid two-phase flow is formed in the heat exchange section and the auxiliary heat exchange section.
With this configuration, it is possible to prepare the conduit including not only the heat exchange section but also the auxiliary heat exchange section as an area for vaporizing the liquid. Therefore, it is possible to more effectively perform vaporization by vaporizing the liquid in a large area.
The vaporization method according to the embodiment further includes a guiding step of guiding the liquid led out in the form of the ascending flow from the conduit to a vaporizing heater for vaporizing the liquid and heating the gas.
With this configuration, since the liquid and the gas led out from the conduit is guided while being kept in the state of the ascending flow, it is possible to suppress the occurrence of the separated flows between the conduit and the vaporizing heater as well. Therefore, it is possible to vaporize the liquid, which is not vaporized by the Stirling engine, with the vaporizing heater and obtain the target gas at high efficiency.
A vaporization apparatus according to the embodiment includes a Stirling engine including a heat exchange unit for cold energy, and a vaporizing tube which is attached to the Stirling engine while covering the heat exchange unit for cold energy and in which liquid circulates so as to come into contact with the heat exchange unit for cold energy. The vaporizing tube is attached to the Stirling engine at an angle set in advance. The angle set in advance is an angle at which an ascending flow of the liquid flowing from a bottom to a top of the heat exchange unit for cold energy can be formed and at which a flowing direction of the ascending flow is adjusted to suppress occurrence of separated flows of the liquid and gas in the vaporizing tube.
With this configuration, it is possible to suppress the occurrence of the separated flows in the vaporizing tube. Therefore, as explained above, even when the flow velocity of the liquid is low, it is possible to maintain the gas-liquid two-phase flow in which the gas and the liquid are mixed without a gas-liquid interface being separated. With the configuration, the liquid in the vaporizing tube comes into contact with the heat exchange unit for cold energy to vaporize. Therefore, it is possible to obtain the target gas at high efficiency.
Specifically, the vaporizing tube includes a heat exchange section that circulates the liquid such that the liquid comes into contact with the heat exchange unit for cold energy, a lead-in section for leading the liquid into the heat exchange section, and a lead-out section for leading out gas vaporized in the heat exchange section and the liquid from the heat exchange section. A channel in the vaporizing tube has a shape for circulating the liquid in a direction having an upward component in the entire range from the lead-in section to the lead-out section.
The vaporizing tube includes a heat exchange section that circulates the liquid such that the liquid comes into contact with the heat exchange unit for cold energy, and a lead-in section for leading the liquid into the heat exchange section. A sectional area of a channel in the led-in section is set smaller than a sectional area of a channel in the heat exchange section.
With this configuration, since the sectional area of the channel in the lead-in section is set smaller than the sectional area of the channel in the heat exchange section, it is possible to set the density of the liquid in the lead-in section higher than the density of the liquid in the heat exchange section. Therefore, it is possible to maintain a state in which a lot of cold energy is retained at a stage before the liquid is guided to the heat exchange section. As a result, it is possible to more effectively perform vaporization in the heat exchange section.
The heat exchange unit for cold energy includes an encapsulating section in which working gas of the Stirling engine is encapsulated, and a plurality of extending sections heat-conductibly coupled to the encapsulating section and extending upward from the encapsulating section. The vaporizing tube includes a heat exchange section which covers at least a part of the encapsulating section and in which the encapsulating section and the liquid come into contact with each other, and an auxiliary heat exchange section which covers the extending sections and in which the extending sections and the liquid come into contact with each other.
With this configuration, since the vaporizing tube includes not only the heat exchange section but also the auxiliary heat exchange section, it is possible to more effectively perform vaporization in a large area.
A vaporization system according to the embodiment includes the vaporization apparatus, a supply source capable of supplying liquid to the vaporizing tube of the vaporization apparatus, and a vaporizing heater for vaporizing the liquid led out from the vaporizing tube and heating gas led out from the vaporizing tube. The supply source supplies the liquid to the vaporizing tube at a flow velocity at which a gas-liquid two-phase flow in which the liquid and the gas are mixed is formed in the vaporizing tube.
With this configuration, it is possible to form the gas-liquid two-phase flow in which the liquid and the gas are mixed in the vaporizing tube. Therefore, the liquid contained in the gas-liquid two-phase flow is vaporized by the heat exchange unit for cold energy of the Stirling engine and the liquid not vaporized by the heat exchange unit for cold energy and led out as an ascending flow from the vaporizing tube is vaporized by the vaporizing heater. Therefore, it is possible to obtain target gas at high efficiency without requiring a complicated process and a complicated configuration.
The vaporizing tube includes a heat exchange section that circulates the liquid such that the liquid comes into contact with the heat exchange unit for cold energy. The supply source supplies the liquid to the vaporizing tube at a flow velocity at which an intermittent flow or an air bubble flow is formed in the heat exchange section.
With this configuration, it is possible to effectively bring the liquid contained in the gas-liquid two-phase flow and the heat exchange unit for cold energy of the Stirling engine into contact with each other by forming the intermittent flow or the air bubble flow in which the liquid circulates uniformly at a relatively low flow velocity. Therefore, it is possible to further improve efficiency of vaporization by the Stirling engine.
The vaporizing heater is provided above the vaporizing tube and receives the liquid and the gas led out from the vaporizing tube in the form of the ascending flow.
With this configuration, it is possible to surely guide the liquid and the gas to the vaporizing heater while suppressing occurrence of separated flows by forming the ascending flow between the vaporizing tube and the vaporizing heater as well. Therefore, it is possible to surely vaporize the liquid contained in the gas-liquid two-phase flow related to the ascending flow with the vaporizing heater. Therefore, with the configuration, it is possible to obtain target gas at higher efficiency.
As explained above, the vaporization method, the vaporization apparatus used for the vaporization method, and the vaporization system provided with the vaporization apparatus according to the present invention are useful for vaporizing the liquid while recovering power using the Stirling engine and is suitable for suppressing occurrence of separated flows of the liquid and the gas in the conduit of the vaporizing tube and maintaining the gas-liquid two-phase flow in which the gas and the liquid are mixed.
Number | Date | Country | Kind |
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2010-131650 | Jun 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/002972 | 5/27/2011 | WO | 00 | 12/5/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/155146 | 12/15/2011 | WO | A |
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