KR101309715B1 - Carbonization device - Google Patents

Abstract

Provided is a carbonization apparatus capable of precisely controlling the temperature in the retort without incurring a time delay and consequently obtaining the desired carbide.

In a carbonization apparatus in which organic dry sludge charged into a retort is carbonized in a low oxygen or anoxic atmosphere under indirect heating, a temperature detecting means and a cooling water vapor supply means are inserted from one side of the retort to an axis portion of the retort, and The combustion amount of the burner and / or the supply amount of cooling steam into the retort by the cooling steam supply means for cooling is controlled so that the temperature in the retort detected by the temperature detecting means falls within a set value.

Carbonization

Description

Carbonization unit {CARBONIZATION DEVICE}

1 is a longitudinal sectional view illustrating a carbonization apparatus according to the present invention;

2 is a partially enlarged view of FIG. 1;

3 is a longitudinal sectional view illustrating another carbonization apparatus according to the present invention.

4 is a partially enlarged view of FIG. 3.

<< description of the sign >>

11, 13; Lhotse 12, 14: retort

21, 23: heating chamber 22, 24: exhaust gas treatment chamber

31-34: burner 52, 56: duct

53, 57: damper 54, 58: exhaust fan

61, 64: double pipe 62, 65: inner pipe

63, 66: appearance 71, 73: thermocouple

75: pressure sampling hole 81, 82: arithmetic unit

91, 92: steam jet hole 94, 98: pump

The present invention relates to a carbonization device. When municipal sewage, industrial wastewater and the like are treated by, for example, an activated sludge method, a new amount of organic sludge is produced. In order to use such sludge effectively, dehydration, drying, carbonization, and using carbide as a soil improving material, fuel, etc. are advanced. This invention relates to the improvement of the carbonization apparatus used when carbonizing organic dry sludge.

Conventionally, a carbonization apparatus as described above includes a furnace body, a retort rotatably mounted over both sidewalls of the furnace body, and a plurality of burners provided in a heating chamber between the furnace body and the retort, A device is known in which an organic dried sludge charged into one of the retorts is carbonized in a low oxygen or anoxic atmosphere under indirect heating by combustion of the burner while rotating the retort (for example, a patent document). 1 and 2).

By the way, when carbonizing organic dry sludge, temperature control at the time of carbonization is important in order to obtain desired carbide | carbonization, and such temperature is generally controlled in the range of 300-900 degreeC. This is because when the temperature is lower than 300 ° C, it is easy to be uncarbonized. On the contrary, when the temperature is higher than 900 ° C, it is easy to be carbonized, and both of them deteriorate as carbides. For this reason, in the above-mentioned conventional carbonization apparatus, a temperature detecting means, for example, a thermocouple, is inserted into a heating chamber between the furnace and the retort, and the heating is performed, for example, so that the detected temperature is within a set value range. The combustion amount of the burner installed in the chamber is controlled. However, in such a conventional carbonization apparatus, what is actually measured is the temperature of the heating chamber between the furnace and the retort, not the temperature in the retort that carbonizes the organic dried sludge. There is a problem that the occurrence of a time delay cannot be avoided and, as a result, a case where desired carbides are often not obtained.

(Patent Document 1) Japanese Patent Application Laid-Open No. 11-37644

(Patent Document 2) Japanese Unexamined Patent Publication No. 2004-277465

The technical problem to be solved by the present invention is to provide a carbonization apparatus capable of precisely controlling the temperature in the retort without incurring a time delay, and as a result, obtaining a desired carbide.

The present invention, which solves the above-mentioned problems, is directed to a carbonization apparatus in which an organic dried sludge charged into a retort is carbonized in a low oxygen or anoxic atmosphere under indirect heating by combustion of a burner formed outside the retort while rotating the retort. And a combustion amount of the burner so that the temperature detection means and the cooling water vapor supply means for cooling are inserted from the one side of the retort to the axis line in the retort, and the temperature in the retort detected by the temperature detection means is within a set value. Or it relates to the carbonization apparatus characterized by controlling the supply amount of the cooling steam to the retort by the cooling steam supply means.

The carbonization apparatus according to the present invention also includes a furnace, a retort rotatably mounted over both sidewalls of the furnace, and a plurality of burners provided in a heating chamber between the furnace and the retort, as in the conventional carbonization apparatus. The organic dried sludge charged into the retort at one end of the retort is carbonized in a low oxygen or anoxic atmosphere under indirect heating by combustion of the burner while rotating the retort.

The carbonization apparatus according to the present invention includes a temperature detecting means inserted into an axis portion in the retort from one side of the retort, and a cooling water vapor supplying means, wherein the temperature in the retort detected by the temperature detecting means is set to a predetermined value. The combustion amount of the burner and / or the supply amount of cooling steam into the retort by the cooling steam supply means is controlled so as to be within the range.

When the temperature in the retort is detected by the temperature detecting means, and the detected temperature is within the range of the set value, combustion of the burner is normally continued as it is, and cooling steam is not supplied into the retort. However, when the detected temperature is lowered beyond the range of the set value, the burner of the burner is usually raised. On the contrary, when the detected temperature is increased beyond the set value, the burner of the burner is usually lowered and cooled in the retort. Supply water vapor. The combustion amount of the burner and the supply amount of cooling steam are controlled according to the degree to which the detected temperature is lowered or increased. In addition, since the temperature of a heating chamber tends to become high temperature by combustion of dry gas, when carbonizing at low temperature (about 300-600 degreeC), cooling steam is always supplied and a detected temperature is set value. If it is in the range of, the supply of cooling steam is continued as it is, and if the detected temperature is lower than the set value, the supply amount of cooling steam is reduced, and if the detected temperature is higher than the set value, For example, the supply amount of cooling steam can be increased. In the carbonization apparatus according to the present invention, since the temperature in the retort carbonizing the organic dried sludge is directly detected, the original temperature detection is accurate. Since the combustion amount of the burner and the supply amount of cooling steam to the retort are controlled based on such an accurate temperature, the temperature in the retort can be accurately controlled without generating a time delay.

When the organic dried sludge is carbonized in the retort, the pressure in the retort varies as well as the temperature. If the temperature is too low, it is easy to be uncarbonized, and on the contrary, if the temperature is too high, it becomes easy to carbonize.However, if the pressure is too low, the atmosphere enters the retort, and the low oxygen or anoxic atmosphere is easily broken. Produced gases such as dry gas and malodorous gas produced by carbonization tend to leak out of the carbonization apparatus, and either of them is unsuitable. For this reason, in the carbonization apparatus which concerns on this invention, the pressure detection means is further inserted in the axis part in the retort from one side of a retort, and the pressure in the retort detected by the pressure detection means is in the range of a set value. It is preferable to control the rotational speed of the exhaust fan for sucking and exhausting the generated gas in the retort and / or the opening degree of the damper provided in the duct to which the exhaust fan is connected.

The means for inserting the temperature detecting means, the cooling water vapor supply means, and the pressure detecting means from one side of the retort to the axis in the retort is not particularly limited, but a multi-tube is provided from one side of the retort to the axis in the retort from the one side of the retort. It is preferable to insert the temperature detecting means, the cooling water vapor supply means, and the pressure detecting means through the multi-tube. For example, the inner tube is used as a sampling tube for the retort pressure while a double tube is inserted into the cantilever from one side of the retort to the axis of the retort, and the thermocouple is exposed from the tip of the inner tube to the retort. Further, a plurality of holes are drilled in the outer pipe of the double pipe to blow out cooling water vapor from the hole into the retort.

(Example)

1 is a longitudinal sectional view illustrating a carbonization apparatus according to the present invention, and FIG. 2 is a partially enlarged view of FIG. 1. The carbonization apparatus illustrated in FIGS. 1 and 2 includes a furnace body 11 and a retort 12 rotatably mounted over both sidewalls of the furnace body 11. In the furnace 11, a heating chamber 21 is formed between the retorts 12, an exhaust gas treatment chamber 22 is formed in communication with the lower end of the heating chamber 21, and the heating chamber 21 is provided. In the plurality of burners 31, burners 32 are also provided in the exhaust gas treatment chamber 22. A charging port 41 is formed at one end of the retort 12, and a discharge port 42 is formed at the other end, and a plurality of pipes are provided at an intermediate part of the heating chamber 21 of the retort 12. The upper exhaust port member 43 is provided. The charging means 41 is connected with a supply means for drying organic sludge, which is not shown in the drawing, and the inside of the retort 12 and the heating chamber 21 are communicated by the exhaust port member 43, and the discharge port 42 ), An outlet hood 44 is mounted to prevent air from entering the retort 12. An exhaust port 51 is formed in the furnace body 11 forming the exhaust gas processing chamber 22, a duct 52 is connected to the exhaust port 51, and a damper 53 and an exhaust fan are connected to the duct 52. 54 is provided. Although not shown in the drawing, the temperature of the heating chamber tends to become high due to the combustion of dry gas, so when carbonizing at low temperatures (about 300 to 600 ° C), the insulation is wound around the retort, or the retort is doubled. It is also possible to suppress the transfer of heat from the heating chamber into the retort by flowing a fluid or the like into the space.

The double pipe 61 is inserted in the axis part in the retort 12 through the outlet hood 44 from one side at the discharge port 42 side of the retort 12. The thermocouple 71 passes through the inner tube 62 in which both ends of the double tube 61 are sealed, and the tip of the thermocouple 71 is exposed from the inner tube 62 into the retort 12, and the proximal end thereof is the inner tube ( Out of 62, it is connected to the computing device 81 via a thermometer 72. Further, a plurality of water vapor ejection holes 91 are formed at the front end side in the retort 12 of the outer casing 63 in which the both ends are sealed in the double pipe 61. The proximal end of the external appearance 63 is connected to the pump 94 via a heater 92 and a flow meter 93, and an arithmetic unit 81 is connected to the pump 94. Although not shown, the computing device 81 is also connected to the fuel supply system of the burner 31 described above.

In the carbonization apparatus illustrated in FIGS. 1 and 2, the organic dried sludge charged from the charging port 41 into the retort 12 is rotated with the retort 12 while being low oxygen or under indirect heating by combustion of the burner 31. Carbonized in an oxygen-free atmosphere, the carbide is discharged from the outlet 42, and stored in the carbide storage hopper not shown in the drawing through the outlet 45 of the outlet hood 44, and the carbide conveyance conveyor not shown. On the other hand, the generated gas such as dry gas or odor gas generated by carbonization is sucked into the path of the retort 12, the exhaust port member 43, the heating chamber 21 and the exhaust gas treatment chamber 22, and the burner is After the combustion gas is subjected to post-combustion by 32, the exhaust port 51, the duct 52, the damper 53, and the exhaust fan 54 are exhausted through the path.

In the carbonization of the organic dried sludge, when the temperature in the retort 12 detected by the thermocouple 71 and the thermometer 72 is within a range of a preset value set in advance in the computing device 81, Combustion of the burner 31 is continued as it is, and water vapor is not blown into the retort 12. However, when the temperature in the retort 12 detected by the thermocouple 71 and the thermometer 72 is lowered out of the range of the preset value set in the computing device 81 in advance, the computing device 81 according to the lowered degree. When the combustion amount of the burner 31 is increased by a signal generated from the upper side, and the temperature in the retort 12 detected on the contrary rises outside the range of the set value, the signal generated by the computing device 81 according to the increased degree is increased. By lowering the combustion amount of the burner 31, the cooling steam is pumped into the retort 12 through the pump 94, the flow meter 93, the heater 92, the exterior 63, and the steam jet hole 91. The jet speed is controlled while controlling the supply amount by the rotation speed control of 94.

3 is a longitudinal sectional view illustrating another carbonization apparatus according to the present invention, and FIG. 4 is a partially enlarged view of FIG. 3. The carbonization apparatus illustrated in FIGS. 3 and 4 also has a furnace body 13 and a retort 14 rotatably mounted over both sidewalls of the furnace body 13, as shown in FIGS. 1 and 2. Doing. In the furnace 13, a heating chamber 23 is formed between the retort 14, an exhaust gas treatment chamber 24 is formed in communication with the lower end of the heating chamber 23, and the heating chamber 23 is formed. ), A plurality of burners 33 are provided, and a burner 34 is also provided in the exhaust gas treatment chamber 24. A charging port 46 is formed at one end of the retort 14, and a discharge port 47 is formed at the other end. In the heating chamber 23 of the retort 14, a plurality of pipe-shaped exhaust port members 48 are provided in the intermediate portion. The charging means 46 is connected to a supply means for drying organic sludge, which is not shown in the drawing, and the inside of the retort 14 and the heating chamber 23 communicate with each other by the exhaust port member 48, and the outlet 47 ), An outlet hood 49 is mounted. An exhaust port 55 is formed in the furnace 13 which forms the exhaust gas processing chamber 24, a duct 56 is connected to the exhaust port 55, and a damper 57 and an exhaust fan are connected to the duct 56. 58) is installed.

On the discharge port 47 side of the retort 14, a double pipe 64 is inserted into the axis portion of the retort 14 through the outlet hood 49 from one side. The thermocouple 73 passes through the inner tube 65 in which both ends of the double tube 64 are sealed, and the tip of the thermocouple 73 is exposed from the inner tube 65 into the retort 14. The base end is connected to the computing device 82 through the thermometer 74 out of the inner tube 65. Moreover, the pressure sampling hole 75 is formed in the front end side in the retort 14 of the inner pipe 65 in which both ends were blocked, and the base end side of this inner pipe 65 is provided to the arithmetic unit 82 through the pressure gauge 76. Moreover, as shown in FIG. Connected. The inner tube 65 also serves as a sampling tube of the pressure in the retort 14. A plurality of water vapor ejection holes 95 are formed in the front end side of the retort 14 of the outer casing 66 in which the both ends are sealed in the double pipe 64. The proximal end of such an exterior 66 is connected to the pump 98 via a heater 96 and a flow meter 97, and an arithmetic unit 82 is connected to the pump 98. The arithmetic unit 82 is also connected to the damper 57 and the exhaust fan 58, and although not shown, it is also connected to the fuel supply system of the burner 33.

In the carbonization apparatus illustrated in FIGS. 3 and 4, the organic dry sludge charged from the charging inlet 46 into the retort 14, as in the carbonization apparatus illustrated in FIGS. 1 and 2, is rotated while the retort 14 is rotated. Carbonization in a low oxygen or anoxic atmosphere under indirect heating by combustion of 33), the carbide is discharged from the outlet 47, through the outlet 50 of the outlet hood 49, through a carbide conveyance conveyor not shown Store in a carbide storage hopper not shown. On the other hand, generated gases such as dry gas and malodorous gas generated by carbonization are sucked into the path of the retort 14, the exhaust port member 48, the heating chamber 23, and the exhaust gas processing chamber 24, and the burner 34 is here. After post-combustion of the product gas with the exhaust gas, the exhaust gas is exhausted through the exhaust port 55, the duct 56, the damper 57, and the exhaust fan 58.

In the carbonization of the organic dried sludge, when the temperature in the retort 14 detected by the thermocouple 73 and the thermometer 74 is within a range of a preset value set in the computing device 82 in advance, Combustion of the burner 33 is continued as it is, and water vapor is not blown out in the retort 14. However, when the temperature in the retort 14 detected by the thermocouple 73 and the thermometer 74 is lowered out of the range of the preset value set in the calculation device 82, the calculation device 82 according to the lowered degree. In the case where the combustion amount of the burner 33 is increased by a signal generated by the slit, and the temperature in the detected retort 14 rises out of the range of the set value, it is generated by the computing device 82 according to the increased degree. By lowering the combustion amount of the burner 33 by a signal, the cooling water vapor is pumped into the retort 14 through the pump 98, the flow meter 97, the heater 96, the exterior 66, and the steam jet hole 95. The jet speed is controlled while controlling the supply amount by the rotation speed control at 98.

In addition, in the carbonization apparatus illustrated in FIGS. 3 and 4, the pressure in the retort 14 detected by the pressure sampling hole 75, the inner tube 65, and the pressure gauge 76 is set in advance by the computing device 82. When it exists in the range of, exhaust of the exhaust fan 58 through the damper 57 is continued as it is. However, when the pressure in the retort 14 detected by the pressure sampling hole 75, the inner tube 65, and the pressure gauge 76 is lowered out of the range of the preset value set in the computing device 82, the lowered value is lowered. Depending on the degree, the opening of the damper 57 is reduced by the signal generated by the calculating device 82, and at the same time or instead, the rotation speed of the exhaust fan 58 is reduced, and the retort detected on the contrary ( If the pressure in 14) rises outside the range of the set value, the opening degree of the damper 57 is increased by a signal generated by the calculating device 82 according to the increased degree, and at the same time or instead of this, The rotation speed of the exhaust fan 58 is raised.

According to the carbonization apparatus of the present invention, it is possible to accurately control the temperature in the retort without causing a time delay, and as a result, there is an effect that a desired carbide can be obtained.

Claims (4)

A carbonization apparatus in which an organic dried sludge charged into a retort is carbonized in a low oxygen or an oxygen-free atmosphere by rotating the retort under indirect heating by combustion of a burner installed outside the retort. The combustion amount of the burner is inserted from one side of the retort into the axis portion of the retort to insert the temperature detecting means, the cooling water vapor supply means and the pressure detecting means, so that the temperature in the retort detected by the temperature detecting means is within the set value. And / or control the supply amount of cooling steam into the retort by the cooling steam supply means, and further generate the product gas in the retort such that the pressure in the retort detected by the pressure detecting means is within a set value range. And a rotation speed of the exhaust fan to suck and exhaust, and / or an opening degree of a damper provided in the duct to which the exhaust fan is connected. The carbonization apparatus according to claim 1, wherein a multiple pipe is inserted from one side of the retort to the axis line in the retort, and a temperature detecting means, a cooling water vapor supply means, and a pressure detecting means are inserted through the multi pipe. . delete delete

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