JP2005270816A - High temperature, high pressure treatment apparatus for organic waste - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high temperature, high pressure treatment apparatus for organic waste capable of economically treating even organic waste with high solid content at high temperature and pressure, without causing blocking inside. <P>SOLUTION: This apparatus decomposes moisture-containing organic waste in a high temperature and pressure condition below a critical pressure, and is provided with a preheater 1 maintained at nearly moisture evaporating temperature, and a reactor 2 directly connected to the preheater 1 and maintained in a vapor phase condition above the critical temperature of water. A double damper type discharge pipe 11 is provided at a lower part of an outlet side of the reactor 2. High temperature and pressure gas extracted from the reactor 2 through a line 10 is led to an outer pipe 3 of the preheater 1 and used as a heat source, then cooled to high pressure water, and led to the discharge pipe 11 from blocking preventing lines 18, 19 to prevent blocking. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an organic waste high-temperature and high-pressure treatment apparatus for decomposing organic waste containing water such as sewage sludge and garbage under high-temperature and high-pressure conditions.

  Currently, the incineration method is the mainstream for treating organic waste such as sewage sludge and garbage. However, it is necessary to design a large incineration plant for incineration, so it is suitable for urban areas, but the incineration method is not suitable for local governments where large amounts of organic waste are not discharged. Therefore, there is an urgent need to develop organic waste treatment technology that can replace incineration. Examples of such alternative technologies include a supercritical processing method and a wet oxidation method.

  The supercritical treatment method is a method of treating organic waste using supercritical water having a critical pressure of water (about 22 MPa) and a critical temperature of water (374 ° C.) or higher (Patent Document 1). Supercritical water is attracting attention as a reaction field for oxidation treatment because of its high reactivity. Actually, the organic waste is oxidatively decomposed under high temperature and high pressure conditions of a pressure of 22 to 25 MPa and a temperature of 600 to 650 ° C.

  In order to perform this supercritical treatment, organic waste must be supplied to the reaction site using a special pump having a discharge pressure of 25 MPa or more. Such a special pump is about 2 to 5 MPa. Unlike a normal pump having a discharge pressure of 2 mm, it is not good at pumping a fluid having a high solid content concentration. For this reason, the upper limit of the solid content concentration of organic waste that can be handled is 10% (water content is 90%), which is inappropriate for the treatment of organic waste with a solid content concentration higher than this (low water content) Met.

  In addition, since the reaction is carried out in a state where organic waste and oxygen are completely dissolved in supercritical water, it is difficult to treat a high-concentration solid. In addition, since the reaction conditions are severe, there are problems such as corrosion of the apparatus, and there is a concern that a lot of cost is required to increase the pressure of oxygen or air as an oxidant to a high pressure.

  On the other hand, the wet oxidation method is a method in which organic waste is oxidatively decomposed under liquid phase conditions that are below the critical point for both temperature and pressure. Since this method has mild reaction conditions compared to the supercritical processing method described above, the equipment cost and running cost are low, and since a pump having a normal discharge pressure can be used, the water content is 90% or less. It is also possible to treat organic waste. However, there is a limit in the degree of oxidation in the wet oxidation method, and there is a problem that nitrogen is converted into ammonia under this condition and the ammonia can hardly be decomposed. Since a separate ammonia treatment device is required to clear the ammonia emission regulations, the result is that equipment costs and running costs increase.

In addition to the above, as shown in Patent Document 2, a method of oxidizing an organic substance under subcritical conditions of not less than the critical temperature of water and not more than the critical pressure has been proposed. The technique disclosed in Patent Document 2 is a technique for treating a water flow carrying a combustible substance at, for example, a pressure of 10 MPa and a temperature of 600 ° C. However, since this is intended for waste having a water flow, there is a problem that the solid content concentration is low and the solid content that can be processed with respect to the apparatus is small. As described above, there has hardly been proposed an apparatus capable of economically treating organic waste having a high solid content concentration at high temperature and high pressure without causing clogging inside the apparatus.
Japanese Patent No. 3440835 Japanese Patent No. 3048385

  The present invention solves the above-mentioned conventional problems and economically treats organic waste with a high moisture content of 90% or less at high temperature and high pressure economically without causing clogging inside. It was made in order to provide a high-temperature and high-pressure treatment apparatus for organic waste.

  In order to solve the above problems, the invention of claim 1 is an apparatus for decomposing organic waste containing water under high-temperature and high-pressure conditions below the critical pressure of water, which is directly connected to the preheater. The preheater is maintained near the moisture evaporation temperature, the reactor is maintained in a gas phase condition above the critical temperature of water, and a double damper type exhaust pipe is installed at the lower part of the reactor outlet side. And a line for preventing clogging for introducing high-pressure water cooled from the high-temperature high-pressure gas extracted from the reactor into the discharge pipe. In the invention of claim 2, high-pressure water obtained by cooling and decompressing the high-temperature high-pressure gas extracted from the reactor is introduced into the discharge pipe. It is preferable to provide a line for guiding the high-temperature and high-pressure gas extracted from the reactor to the outer tube of the preheater, and use the high-temperature and high-pressure gas as a heat source for the preheater and then guide it to the line for preventing clogging.

  The organic waste high-temperature and high-pressure treatment apparatus of the present invention comprises a preheater maintained at a high-temperature and high-pressure condition below the critical pressure of water and a reactor of the same pressure directly connected thereto, and the organic waste is preheated. The temperature is raised to near the water evaporation temperature in the vessel. At this time, troubles such as clogging can be prevented even when the organic matter is solubilized by hydrolysis or thermal decomposition, and the organic waste has a high solid content concentration with a moisture content of 90% or less. The organic waste that exits the preheater enters the reactor, and the organic matter is oxidatively decomposed under gas phase conditions above the critical temperature of water. In addition, it is preferable to provide a stirring conveyance means inside the preheater and the reactor, respectively, and the decomposition residue is conveyed toward the outlet by the stirring conveyance means.

  The residue oxidatively decomposed in the reactor is discharged from the discharge pipe at the lower part on the outlet side of the reactor. However, because of the double damper type, the reaction product can be taken out without reducing the internal pressure of the reactor. In order to prevent clogging of the residue inside the discharge pipe, high-pressure water cooled from the high-temperature high-pressure gas extracted from the reactor or high-pressure water cooled from the reactor and cooled / depressurized is prevented from clogging. It introduce | transduces into the said discharge pipe through the line for. The inside of the discharge pipe is washed with this high-pressure water, and blockage is reliably prevented.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
In FIG. 1, 1 is a preheater, and 2 is a reactor directly connected to the preheater 1. The preheater 1 has a double tube structure with an outer tube 3. The reactor 2 is provided with a heater 4 on the outer periphery, and the inside is maintained at a water evaporation temperature or higher. The inside of the preheater 1 and the reactor 2 is maintained at a high pressure below the critical pressure of water, for example, 4 MPa. Since the preheater 1 and the reactor 2 are directly connected, the inside is kept at the same pressure. Inside the preheater 1 and the reactor 2, screw type or paddle type stirring and conveying means 5 and 6 are provided, respectively.

  Organic waste containing water such as sewage sludge and garbage is injected into the high-pressure preheater 1 by the slurry injector 7. The slurry injector 7 is a cylinder pump provided with a piston 8, and pushes down the piston 8 with high-pressure water sent from a high-pressure water pump 9 to inject organic waste into the high-pressure preheater 1. In the preheater 1, solubilization of organic substances is performed by hydrolysis or thermal decomposition. The organic waste that has passed through the preheater 1 is sent to the reactor 2, and the organic matter is oxidatively decomposed under gas phase conditions above the critical temperature of water. The decomposed gas is extracted from the line 10, and the remainder (liquid, residue) is discharged from a discharge pipe 11 provided at the lower rear end of the reactor 2.

  The high-temperature and high-pressure gas in the reactor 2 is directly introduced into the outer tube 3 of the preheater 1 through a line 10 connected to the upper portion of the reactor 2 and used as a heat source of the preheater 1. Thus, since the high-temperature high-pressure gas extracted from the reactor 2 is used as a heat source for the preheater 1, energy is not wasted. The high-temperature and high-pressure gas introduced into the outer tube 3 of the preheater 1 is cooled by heating the preheater 1 and becomes drain water. This high-temperature and high-pressure drain water is cooled to near room temperature in the condenser 12. Since the drain water is derived from the gas in the reactor 2, since no residue is contained, the condenser 12 is not clogged during cooling, and the capacitor 12 can be downsized.

  Even in the case where harmful components such as cyan are present in the waste liquid, cyan and the like can be decomposed by cooling for a sufficient time under a temperature condition of 200 ° C. to moisture evaporation temperature. For this reason, it is preferable to gradually cool using a serpentine capacitor 12.

  As described above, the organic waste injected into the preheater 1 is heated near the water evaporation temperature under high pressure conditions, and solubilization of the organic matter is performed by hydrolysis or thermal decomposition. The organic waste that has exited the preheater 1 enters the reactor 2, and the organic matter is oxidized and decomposed under the gas phase conditions above the critical temperature of water by the injected oxygen to become gas, liquid, and residue. Gas is extracted through line 10, while liquid and residue are removed from discharge tube 11.

  The discharge pipe 11 has a double damper structure with upper and lower valves 14 and 15. As shown in FIG. 2A, the upper valve 14 is normally opened and the lower valve 15 is closed to discharge liquid and residue. Drop into tube 11. At this time, the valve 16 is closed, the valve 17 is opened, and high-pressure water is allowed to flow through the blocking line 19. When the residue is taken out, the upper valve 14 is closed and the lower valve 15 is opened, and the valve 17 is closed and the valve 16 is opened to prevent the high pressure water from being blocked from the line 18 for blocking the high pressure water. And drain the liquid and residue. Thus, in the invention of claim 1, the residue is discharged by introducing the high-pressure water that has cooled the high-temperature high-pressure gas into the discharge pipe 11, thereby preventing the blockage.

  FIG. 3 shows an embodiment of the invention of claim 2, which is different in that a pressure reducing means 13 is provided at the subsequent stage of the capacitor 12, and the pressure is reduced by using a pressure loss when high pressure water flows through the pressure reducing means 13. Yes. Even after passing through the decompression means 13, the high-pressure water is sufficiently higher than the atmospheric pressure. In this embodiment, as shown in FIG. 3, only the blocking line 19 is connected to the lower side of the valve 15 on the lower side of the discharge pipe 11.

  In the second aspect of the invention, as shown in FIG. 4A, the upper valve 14 is normally opened and the lower valve 15 is closed to drop the liquid and residue into the discharge pipe 11. The decompressed high-pressure water is always allowed to flow through the blocking line 19. When taking out the residue, the upper valve 14 is closed and the lower valve 15 is opened. The internal pressure of the discharge pipe 11 at the upper part of the residue is higher than the lower part of the residue to which reduced high-pressure water is introduced. For example, a differential pressure of about 0.3 MPa is generated. It is discharged as shown in FIG. 4B. A large differential pressure is advantageous for residue discharge, but when the upper valve 14 is opened after residue discharge, the reaction system is adversely affected by the difference between the internal pressure of the discharge pipe 11 and the internal pressure of the reactor 2. , About 0.3 MPa is preferable.

  FIG. 5 shows another embodiment of the second aspect of the present invention. Also in this embodiment, the upper valve 14 is normally opened and the lower valve 15 is closed to drop the liquid and residue into the discharge pipe 11 and the decompressed high-pressure water to the line 19 for preventing clogging. Let it flow. When taking out the residue, when the upper valve 14 is closed and the lower valve 15 is opened, the residue falls due to the differential pressure as shown in FIG. 6B. Thereafter, the valve 17 is closed, the valve 16 is opened, and the high-pressure water reduced in pressure is caused to flow from the line 18 for preventing clogging into the discharge pipe 11 to completely discharge the liquid and the residue. According to this embodiment, the most reliable prevention of clogging is possible by the combined use of differential pressure and high-pressure water cleaning.

  In this way, a mixture of gas, liquid and residue is discharged from the lower end of the discharge pipe 11. These gases are separated by the gas-liquid / solid separator 20, and the solid-liquid drainage is recovered by the drain tank 21.

  As explained above, according to the present invention, organic waste containing water such as sewage sludge and garbage can be decomposed under high temperature and high pressure conditions. In particular, organic waste with a moisture content of less than 90% can be blocked by combining technologies such as solubilization of organic substances in the preheater, the use of stirring and conveying means, and cleaning of the discharge pipe using a line for preventing clogging. Oxidative decomposition can be performed without fear.

It is sectional drawing which shows embodiment of invention of Claim 1. It is operation | movement explanatory drawing of a discharge pipe. It is sectional drawing which shows embodiment of invention of Claim 2. It is operation | movement explanatory drawing of a discharge pipe. It is sectional drawing which shows other embodiment of invention of Claim 2. It is operation | movement explanatory drawing of a discharge pipe.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Preheater 2 Reactor 3 Outer tube 4 Heater 5 Stirring conveyance means 6 Stirring conveyance means 7 Slurry injector 8 Piston 9 High pressure water pump 10 Line 11 Discharge pipe 12 Capacitor 13 Decompression means 14 Valve 15 Valve 16 Valve 17 Valve 18 Prevention of blockage Line 19 Blocking prevention line 20 Gas-liquid / solid separator 21 Drain tank

Claims (3)

  A device that decomposes organic waste containing water under high-temperature and high-pressure conditions below the critical pressure of water. It consists of a preheater and a reactor directly connected to it. The reactor is maintained in a gas phase condition above the critical temperature of water, a double damper type discharge pipe is provided at the lower part on the outlet side of the reactor, and high-pressure water cooled from the high-temperature and high-pressure gas extracted from the reactor is used. A high-temperature high-pressure treatment apparatus for organic waste, characterized in that a line for preventing clogging introduced into the discharge pipe is provided.   A device that decomposes organic waste containing water under high-temperature and high-pressure conditions below the critical pressure of water. It consists of a preheater and a reactor directly connected to it. The reactor is maintained in a gas phase condition above the critical temperature of water, a double damper type discharge pipe is provided at the lower part on the outlet side of the reactor, and high-pressure and high-pressure gas extracted from the reactor is cooled and decompressed. A high-temperature and high-pressure treatment apparatus for organic waste, characterized in that a line for preventing clogging for introducing water into the discharge pipe is provided.   The high-temperature and high-pressure of organic waste according to claim 1, wherein the high-temperature and high-pressure gas extracted from the reactor is led to an outer tube of the preheater and used as a heat source for the preheater, and then led to a line for preventing clogging. Processing equipment.

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