Patent Application
20110194905
The present invention relates to a conveying device which exchanges an object to be conveyed, between two regions which are under conditions having a large pressure difference, such as a conveying device for transferring hydrate pellets from a high-pressure condition to a low-pressure condition (or from a low-pressure condition to a high-pressure condition) employed in a natural gas hydrate manufacturing plant, for example.
A conventional operation of manufacturing gas hydrate pellets (e.g., natural gas hydrate pellets and the like) includes: a generation process of generating a gas hydrate in a high-pressure environment of about 5.4 MPa; a molding process of compressing the generated snow-powder-form hydrate and processing the hydrate into pellets each shaped like a ping-pong ball; a cooling process and a depressurizing process of cooling and depressurizing the pellets; and a storing process of storing the pellets in a pellet storage tank under atmospheric pressure (see Patent Document 1).
The depressurizing process includes: filling the inside of a conveying device (reduced-pressure drum) to which the pellets are transferred, with a hydraulic fluid (liquid propane, for example) which is made of a gas different from a raw-material gas; and flushing the hydraulic fluid out through a flush valve to thus depressurize the inside of the reduced-pressure drum to atmospheric pressure. This configuration eliminates the need to raise the pressure of a purge gas, which has flowed into the storage tank and is being at atmospheric pressure, again up to the gas pressure of the raw-material gas, which is about 5.4 MPa. This configuration thus enables suppression of power consumption in a gas hydrate manufacturing plant.
This configuration, however, involves a problem of increasing the size of entire facilities due to the need for providing as ancillary facilities a system recovering the hydraulic fluid (liquid propane, for example) accompanying the pellets. When a plant to mass-produce gas hydrate pellets for a commercial purpose is to be built, especially, an apparatus of manufacturing gas hydrate pellets becomes large in size. In association with the large size of the apparatus, the capacity occupied by the ancillary facilities also becomes large in scale. To address this, size reduction of the entire facilities is desired. In other words, the size reduction of the manufacturing apparatus and of the ancillary facilities is desired while the production amount of the gas hydrate pellets is increased.
The present invention is made to address the above problems. An object of the present invention is to provide a conveying device used under a condition having a large pressure difference which is observed during a process such as a depressurizing process in an operation of manufacturing gas hydrate pellets and a method of controlling the same, the conveying device requiring less ancillary facilities, being small in size, and achieving high-speed processing while achieving secure blockage of pressure.
A conveying device according to the preset invention for achieving the above-described object, which is used under conditions having a large pressure difference, is a conveying device including: a casing including a spherically-formed valve chamber in a center portion thereof which has one side connected to a high-pressure pipe on a high-pressure side and another side connected to a low-pressure pipe on a low-pressure side; a spherical valve rotatably supported inside the casing; a gap section which is a gap formed between the casing and the spherical valve; a high-pressure-side seal which seals the high-pressure pipe and the gap section from each other; and a low-pressure-side seal which seals the low-pressure pipe and the gap section from each other, the conveying device characterized in that the conveying device conveys, with rotation of the spherical valve, an object to be conveyed which is housed in a conveying chamber formed by boring a portion of the spherical valve, the conveying chamber including an opening which corresponds to the high-pressure pipe or the low-pressure pipe.
This configuration eliminates the need for ancillary facilities of a system of recovering a hydraulic fluid, and the like, and thus can provide the conveying device according to the present invention as a small-sized conveying device. In addition, the conveying chamber is formed by opening a portion of the spherical valve. Thus, the high-pressure side and the low-pressure side do not communicate with each other. Since the seals of a donut shape, for example, exert their functions due to the pressure difference, it is possible to block the pressure securely even under a condition having a large pressure difference. Here, the opening of the conveying chamber may be formed large as long as the opening does not communicate with the high-pressure pipe and the low-pressure pipe at the same time.
In addition, the conveying device according to the present invention can be provided as a conveying device which performs processing with high speed, since the conveying device can convey objects to be conveyed, by rotating the spherical valve continuously. Further, a gate valve or the like may cause such an operation error that a gate is pushed by the action of a pressure difference and sliding the gate thus becomes difficult. However, the conveying device according to the present invention can prevent the occurrence of such operation error, since rotating the spherical valve enables achievement of the same effect as that achieved by switching the valve.
The above-described conveying device used under conditions having a large pressure difference is characterized in that a pressure of the gap section is controlled by connecting the high-pressure pipe and the gap section to each other via a high-pressure relief line including a high-pressure relief valve, and by connecting the low-pressure pipe and the gap section to each other via a low-pressure relief line including a low-pressure relief valve.
This configuration brings about a period, in the middle of the rotation of the conveying chamber, for example, from the high-pressure side to the low-pressure side, where the conveying chamber is completely blocked by the two seals from the high-pressure side and the low-pressure side. In this period, it is possible to control the pressure of the conveying chamber and the gap section, which are isolated from both the high-pressure side and the low-pressure side, by controlling the high-pressure relief valve or the low-pressure relief valve. This prevents an abrupt change of the pressure of the conveying chamber, and thus can reduce the load on the seals. This resultantly eliminates the need for strengthening a sealing mechanism, such as increasing the thickness of a seal member to increase its strength, even in a case where the pressure difference is particularly large. Thus, the conveying device can be made small.
The above-described conveying device used under conditions having a large pressure difference is characterized in that the high-pressure pipe and the low-pressure pipe are connected to the casing in such a manner that the high-pressure pipe and the low-pressure pipe are located so as to face each other with the spherical valve interposed in between.
According to this configuration, the high-pressure pipe and the low-pressure pipe are located apart from each other with the casing interposed in between. Thus, the opening of the conveying chamber can be formed large. In other words, even in a case where a large opening is formed in the spherical valve, the high-pressure pipe and the low-pressure pipe are less likely to communicate with each other. It is thus possible to make the capacity of the conveying chamber large for the spherical valve, and thus to increase the amount of conveying objects to be conveyed. As a result, the conveying device can be made small in size for the amount of the objects to be conveyed.
A method for controlling the above-described conveying device according to the preset invention for achieving the above-described object is characterized in that a difference in pressure between the conveying chamber and the high-pressure pipe or of the low-pressure pipe is lessened by pressurizing the gap section with control of the high-pressure relief valve in a case where the conveying chamber rotates to communicate with the high-pressure pipe, and by depressurizing the gap portion with control of the low-pressure relief valve in a case where the conveying chamber rotates to communicate with the low-pressure pipe.
This configuration can prevent an occurrence of seal erosion in which the objects to be conveyed burst into the gap section side at the moment when an end portion of the conveying chamber passes the seal and the gap section is communicated with the high-pressure pipe while the spherical valve is rotating to convey the objects to be conveyed, for example. Thus, the durability of the seals is improved. The seals can be thereby formed with a simple configuration even for a case where there is a particularly large pressure difference between the high-pressure side and the low-pressure side. Accordingly, it is possible to provide a compact conveying device. In addition, this configuration can solve the problem of the seal erosion which may otherwise break the objects to be conveyed if the objects are fragile.
A gas hydrate manufacturing apparatus according to the present invention for achieving the above-described object is a gas hydrate manufacturing apparatus including a high-pressure region and a low-pressure region which is characterized in that the above-described conveying device is installed on a boarder having a pressure difference which is a position connecting the high-pressure region and the low-pressure region. This configuration eliminates the need for large facilities of a system for recovering a liquid accompanying the conveying device and thus can make the apparatus compact and make the cost low. This configuration can also improve the area efficiency in the gas hydrate manufacturing plant.
Moreover, the objects to be conveyed may be broken by the seal erosion if the objects are fragile gas hydrate pellets. This breakage degrades the yield of the pellets which are the products. The above configuration can thus improve the production efficiency of the gas hydrate pellet manufacturing plant itself.
Furthermore, if the conveying chamber formed by opening the spherical valve has a tapered form in which the conveying chamber becomes narrower from the opening toward the bottom, it is possible to prevent the objects to be conveyed, which have been supplied to the conveying chamber, from clogging the inside of the conveying chamber. Thus, even if the conveying device is small in size, the conveying device can efficiently convey the objects to be conveyed. In other words, this tapered form can solve the problem of making the capacity of the conveying chamber smaller than the actual capacity thereof, which would otherwise occur in a case where the objects to be conveyed clog the inside of the conveying chamber. Furthermore, if the conveying chamber is formed by hollowing out the inside of the spherical valve, the capacity of the conveying chamber can be increased, and the size reduction of the conveying device can be achieved as well.
According to the conveying device of the present invention used under a condition having a large pressure difference and the method of controlling the same, it is possible to provide a conveying device requiring less ancillary facilities, being small in size, and achieving high-speed processing while achieving secure blockage of pressure, and to provide a method of controlling the same. As a result, the conveying device and the method of controlling the same are further capable of improving the capacity efficiency in facilities such as a gas hydrate manufacturing plant, for example.
With reference to the drawings, a conveying device in a gas hydrate manufacturing apparatus and a method of controlling the conveying device according to an embodiment of the present invention will be described below.
An operation of manufacturing a gas hydrate includes: a generation process of generating a gas hydrate; a molding process of compacting the snow-powder-form gas hydrate to form the gas hydrate into pellets each shaped like a ping-pong ball, for example; a cooling process and a depressurizing process of cooling and depressurizing the pellets; and a storing process of storing the pellets.
Pellets m molded in a previous process under the conditions where the pressure is about 5.4 MPa and the temperature is about 4° C. are cooled by a primary cooler 2 filled with a sealing liquid L such as liquid propane, for example. The pellets m are then depressurized by a conveying device 1 and transferred to a secondary cooler 3 which is at atmospheric pressure (0.1 MPa). Out of the sealing liquid L, only the pellets m are transported by a screw conveyer 4. The pellets pass a partition valve 5 and are stored in a pellet storage tank 6 which is at atmospheric pressure and about −20° C.
Moreover, the gap section 16 is communicated with the high-pressure pipe 21 via a high-pressure relief line 17 having a high-pressure relief valve 18. The gap section 16 is likewise communicated with the low-pressure pipe 22 via a low-pressure relief line 19 having a low-pressure relief valve 20. Controlling the relief valves enables controlling the pressure of the gap section 16. In this respect, the size of the spherical valve 11 is assumed to be about 2 m in diameter, if each pellet m is about the size of a ping-pong ball.
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In addition, consider a case, for example, where there is a difference between the pressure of the low-pressure pipe 22 and the pressures of the conveying chamber 12 and the gap section 16. In this case, there is a risk of an occurrence of seal erosion in which the pellets m burst into the low-pressure pipe 22 side due to the pressure difference at the moment when an end portion of the opening 23 of the conveying chamber 12 passes the low-pressure-side seal 14. This may seriously degrade the durability of the low-pressure-side seal 14. There is also a risk of breakage of the objects to be conveyed, if the objects are fragile objects like the pellets m. The present invention, however, can prevent the afore-mentioned problems because the inside of the conveying chamber 12 is depressurized step by step, i.e., changed from the high-pressure region to the mid-pressure region, and then changed from the mid-pressure region to the low-pressure region in the above-described manner, and the conveying chamber 12 is thus brought into a state where the conveying chamber 12 has no pressure difference with other regions when communicating with the other regions by the rotation of the spherical valve 11.
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By repeating the above processes, the conveying device 1 can continuously convey the objects to be conveyed from the high-pressure side to the low-pressure side or from the low-pressure side to the high-pressure side. Accordingly, the conveying device 1 can be provided as a conveying device which has a high conveying performance with respect to the size of the device.
In the afore-mentioned embodiment, the conveying device in the gas hydrate manufacturing apparatus has been described. The conveying device 1 according to the present invention, however, is not limited to this, but is applicable to other cases where an object needs to be conveyed under condition having a large pressure difference.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2008-292683 | Nov 2008 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2009/069252 | 11/12/2009 | WO | 00 | 4/11/2011 |
