JP2007231062A - Gasification system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gasification system capable of improving energy conversion efficiency and of producing toxic substance-free gas. <P>SOLUTION: The gasification system includes a stationary bed-type gasifier 11 with a pyrolyzing oven 21 functioning to produce gas and char by partially combusting and/or pyrolyzing feedstocks such as biomass and/or wastes and a low-flow type entrained bed oven 12 fed with the gas and char produced in the stationary bed-type gasifier 11 and functioning to partially combust and/or pyrolyze the char thus fed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gasifier for using biomass, waste, or the like as a raw material, gasifying it, and using it for power generation or liquid fuel.

  As this type of gasifier, a fixed-bed downdraft type is known. As shown in FIG. 5, there are a raw material hopper 101, a cutting device 102 for cutting the raw material from the raw material hopper 101, a vertical raw material pipe 103 whose upper end is connected to the cutting device 102, and a raw material pipe 103. And a pyrolysis furnace 105 to which the raw material is supplied by the supply device 104, and the supplied raw material is partially burned and / or pyrolyzed to produce gas and char (unburned carbon). A fixed bed type gasification furnace 106 for generating a solid system), a horizontal gas pipe 107 having one end connected to the gasification furnace 106, a cyclone 108 having the other end connected to the gas pipe 107, and a gasification furnace It is known that includes a forced air blower 109 that sends air to 106 and a discharge device 110 that discharges char from the gasification furnace 106.

  In this conventional gasifier, energy corresponding to 3 to 20% is discharged as char with respect to the amount of energy of the input raw material. Therefore, energy conversion efficiency is poor.

  Further, the produced gas contains harmful substances including tar. Since harmful substances cause problems such as blocking the gas flow path, it is difficult to supply them to an internal combustion engine or the like without treatment. A scrubber (a dust collector using water) is used downstream of the cyclone for the treatment of harmful substances, but the scrubber needs to be provided with a water treatment facility, and the structure of the gasifier becomes complicated.

  An object of the present invention is to provide a gasifier capable of improving the energy conversion efficiency and generating a gas containing no harmful substances.

  The gasification apparatus according to the present invention includes a fixed bed gasification furnace with a pyrolysis furnace that generates a gas and char by partially burning and / or pyrolyzing a raw material, and a gas and char generated in the fixed bed gasification furnace. And a low-flow-rate entrained bed furnace that partially burns and / or thermally decomposes the supplied char.

  In the gasifier according to the present invention, the char generated in the fixed bed gasifier is further partially burned and / or pyrolyzed in the low flow rate entrained bed furnace, so that the energy conversion efficiency can be improved. Since the time for partial combustion and / or thermal decomposition becomes longer, the concentration of harmful substances such as tar in the product gas can be greatly reduced.

  Furthermore, a downward fluidizing agent port is provided at the bottom of the low-flow-rate spouted bed furnace, and an air storage chamber is connected to the fluidizing agent port. When a means for supplying at least one of gas, air, water vapor, and oxygen generated in a gasification furnace is provided, the fluidizing agent is changed depending on the temperature conditions in the furnace, the amount of char supply, the amount of heat generated in the generated gas, and the like. It can be selected and supplied, and harmful substances can be appropriately reduced.

  In addition, if the bottom of the low-flow-rate spouted bed furnace is tapered upward and extends upward from the fluidizer port, the flow speed is relatively high at the bottom of the low-flow-flow-type spouted bed furnace. It can be vigorously stirred, crushed, and atomized, and the flow rate is relatively slow above the bottom of the low-flow-rate spouted bed furnace. Can be secured.

  Further, means for discharging gas from the low flow rate type spouted bed furnace, means for recovering drain contained in the gas discharged from the low flow rate type spouted bed furnace, and spraying the recovered drain into the low flow type spouted bed furnace The drainage of the low-flow-rate spouted bed furnace becomes unnecessary. Furthermore, the combustion in the furnace can be appropriately suppressed by the drain sprayed in the low flow velocity type entrained bed furnace, and the generated gas can be prevented from being unnecessarily burned (consumed).

  According to the present invention, it is possible to improve energy conversion efficiency and generate a gas that does not contain harmful substances.

  Embodiments of the present invention will be described below with reference to the drawings.

  Referring to FIG. 1, the gasifier includes a fixed bed type downdraft gasification furnace 11 and a low flow rate entrained bed furnace 12.

  The gasification furnace 11 is provided with a pyrolysis furnace 21 and a char discharge device 22. The pyrolysis furnace 21 is provided with a raw material supply device 23. The raw material supply device 23 is provided with a raw material hopper 24. The raw material hopper 24 is provided with a raw material cutting device 25. The raw material supply device 23 and the raw material cutting device 25 are connected by a vertical raw material pipe 26. The gasification furnace 11 and the pyrolysis furnace 21 are connected to an air pipe 28 extending from a forced blower 27.

  The spouted bed furnace 12 is provided with a char hopper 31 and a char supply device 32. The char hopper 31 is provided with a char cutting device 33. The char supply device 32 and the char cutting device 33 are connected by a vertical char pipe 34.

  The spouted bed furnace 12 includes a vertical cylindrical free board portion 12A and an upward tapered furnace bottom portion 12B connected to the lower end thereof.

  A generated gas main line 41 extends from near the bottom of the body wall of the gasification furnace 11 toward near the bottom of the free board portion 12A. The raw material cutting device 22 and the char hopper 31 are connected by a char supply pipe 42. A gas pipe 44 extends from the vicinity of the top of the free board portion 12A toward the internal combustion engine 43. A drain spray nozzle 45 is provided in the middle of the height of the free board portion 12A.

  Referring to FIGS. 2 and 3, a fluidizer port 46 is opened downward at the lower end of the furnace bottom 12B. A dispersion plate 47 is fitted to the fluidizer port 46. Further, an air storage chamber 48 is communicated with the fluidizing agent port 46.

  The product gas main line 41 is provided with a switching valve 51. A generated gas sub-line 52 extends from the switching valve 51 toward the storage chamber 48.

  The gas pipe 44 is sequentially provided with a cyclone 61, a heat exchanger 62, and a cooling unit 63 in the gas flow direction. One end of a char recovery pipe 64 is connected to the bottom wall of the cyclone 61. The char collection pipe 64 is provided with a char storage tank 65. The char collection pipe 64 extends from the char storage tank 65 toward the char supply pipe 42, and is joined in the middle of the char collection pipe 64. An air line 66 extends to the storage chamber 48 via the heat exchanger 62. A pusher fan 67 is provided upstream of the heat exchanger 62 in the air line 66, and an air valve 68 is provided downstream thereof.

  A mixed gas line 71 extends in parallel with the air line 66 to the air storage chamber 48. The mixed gas line 71 is sequentially provided with a steam boiler 72, an oxygen mixer 73, and a mixed gas valve 74 in the gas flow direction. A drain pipe 75 extends from the gas cooling unit 63 to the drain spray nozzle 45. The drain pipe 75 is provided with a drain tank 76 and a pump 77.

  2 and 3 conceptually show the lower part of the spouted bed furnace 12. Through the generated gas main line 41, the generated gas is blown out in the tangential direction of the inner surface of the free board portion 12A. The flow of the blown out product gas is in the direction indicated by the thick arrow in FIG. The number of drain spray nozzles 45 is three here. The three drain spray nozzles 45 are arranged at regular intervals in the circumferential direction of the free board portion 12A and spray the drain toward the downstream in the flow direction of the generated gas.

Assuming that the diameter of the lower end of the furnace bottom portion 12B is d _B and the diameter of the upper end of the furnace bottom portion 12B, that is, the diameter of the free board portion 12A is d _FB , the ratio A _S = d _B / d _FB = 0.01 to 0.3 Degree. In this _AS range, the rate of change (r = U _B / U _FB ) between the superficial velocity U _B of the furnace bottom portion 12B and the superficial velocity U _FB of the free board portion 12A is large, and the free board portion 12A The superficial velocity is drastically reduced compared to the superficial velocity of the furnace bottom 12B, resulting in a low-speed flow. Therefore, while maintaining the spouted bed height low, the time required for the gasification reaction rate of char and the decomposition reaction of tar and the like is ensured.

  FIG. 4 shows the dispersion plate 47 in detail. The dispersion plate 47 is a disc-shaped plate in which a large number of round holes having a diameter of about 5 mm are formed in a staggered manner, and has a function of rectifying the fluidizing agent and a function of holding char.

Raw materials such as biomass and waste having a water content of about 15% WB are stored in the raw material hopper 24. The stored raw material is cut out from the raw material hopper 24 while being crushed by the raw material cutting device 25, and then fed into the pyrolysis furnace 21 by the raw material supply device 23. High-temperature air is fed into the pyrolysis furnace 21 and the gasification furnace 11 through the air pipe 28 from the forced air blower 27. The supplied raw material is partially burned at a total air ratio of about 0.25 through a pyrolysis furnace 21 and a gasification furnace 11, and as a result, a pyrolysis gas mainly composed of volatile components and moisture is obtained by a pyrolysis reaction. And char, which is a solid substance. The separated char is stored at the bottom of the gasification furnace 11 to form a deposition layer called a char bed. The temperature of the deposited layer is 800-900 ° C. A space is formed above the deposition layer in the gasification furnace 11, and the pyrolysis gas passing through the space and the tar in the char are pyrolyzed into char by the high-temperature air introduced into the space. . The pyrolysis gas is allowed to pass through the gap between the chars of the deposited layer, thereby generating CO and H ₂ gas and decomposing the tar content in the gas.

The gas generated in the gasifier 11 is sent to the spouted bed furnace 12 through the generated gas main line 41. The tar concentration in the gas at this time is about 1000 mg / Nm ₃ . The char deposited at the bottom of the gasification furnace 11 is discharged from the gasification furnace 11 by the char discharge device 22, and is sent to the char hopper 31 through the char supply pipe.

  The char stored in the char hopper 31 is cut out by the char cutting device 33 and supplied to the free board portion 12A of the spouted bed furnace 12 by the char supply device 32. Below the supplied char, the product gas is sent by the product gas main line 41. In the bottom 12B of the spouted bed furnace 12, the char is vigorously stirred at a relatively high flow rate, and most of the char is atomized.

  The fluidizing agent is fed into the spouted bed furnace 12 through the air storage chamber 48. One of the following I to IV is selected as the fluidizing agent in accordance with the state of the entrained bed furnace 12 such as the furnace temperature and the amount of char input. Although not shown, the temperature in the furnace is detected by a thermocouple thermometer installed in the free board portion 12A. The char input amount is detected by a level meter installed in the char hopper 31.

I. Steam and oxygen When the char load (input amount) on the spouted bed furnace 12 is small,
The air valve 68 is turned off, the mixed gas valve 74 is turned on, and the switching valve 51 turns off the flow rate to the product gas sub-line 52.

II. Part of the product gas and hot air When the in-furnace temperature of the spouted bed furnace 12 is lower than 800-900 ° C,
The air valve 68 is turned on, the mixed gas valve 74 is turned off, and the switching valve 51 turns on the flow rate to the product gas sub-line 52.

III. Part of the product gas, steam and oxygen When the char load (input amount) on the spouted bed furnace 12 is large,
The air valve 68 is turned off, the mixed gas valve 74 is turned on, and the switching valve 51 is turned on in the flow rate to the product gas sub-line 52.

IV. A part of the product gas, high-temperature air, water vapor, and oxygen When the load (input amount) of char on the spouted bed furnace 12 is large and the in-furnace temperature of the spouted bed furnace 12 is lower than 800 to 900 ° C,
The air valve 68 is turned on, the mixed gas valve 74 is turned on, and the switching valve 51 turns on the flow rate to the product gas sub-line 52.

The inner temperature of the spouted bed furnace 12 is maintained in an atmosphere of about 800 to 900 ° C. by the above selected fluidizing agent. Under this atmosphere, the pulverized char generates CO and H ₂ by a water gasification reaction represented by the following formula (1).

C + H ₂ O → CO + H ₂ (1)
The tar content contained in the product gas is partially burned and reduced by the oxygen content in the fluidizing agent. Moreover, decomposition | disassembly of a tar content is accelerated | stimulated by making it contact with the intervening char at the temperature of about 800-900 degreeC. The tar concentration of the product gas discharged from the spouted bed furnace 12 is greatly reduced.

  The product gas discharged from the spouted bed furnace 12 is sent to the internal combustion engine 43 via the cyclone 61, the heat exchanger 62, and the gas cooling unit 63 sequentially. The cyclone 61 captures char in the product gas. The captured char is stored in the char storage tank 65 and then returned to the char hopper 31. In the heat exchanger 62, the air sent from the forced air blower 67 is heat-exchanged with the heat of the product gas to be a high temperature. In the gas cooling unit 63, the generated gas is cooled by the cooling air, and moisture and tar in the gas are condensed and recovered as drain. The collected drain is sent to the drain spray nozzle 45 via the tank 76 and the pump 77. The drain sprayed into the spouted bed furnace 12 contributes to the water gasification reaction and moderately suppresses combustion. Thereby, it is possible to prevent the generated gas from being unnecessarily burned (consumed).

It is a schematic block diagram of the gasification apparatus by this invention. It is an expanded vertical sectional view of the lower part of the spouted bed furnace of the trunk gasifier. FIG. 3 is a horizontal sectional view taken along line III-III in FIG. 2. FIG. 4 is a horizontal sectional view taken along line IV-IV in FIG. 2. It is a schematic block diagram of the gasifier which shows a prior art example.

Explanation of symbols

11 Gasifier
12 Fluidized bed furnace
12A Furnace bottom
45 Drain spray nozzle
46 Fluidizer port
48 Respiratory chamber
63 Cooling unit

Claims (4)

  A fixed bed gasification furnace with a pyrolysis furnace that generates gas and char by partially burning and / or pyrolyzing the raw material, and a char and char supplied with the gas and char generated in the fixed bed gasification furnace A gasifier comprising a low-flow-rate entrained bed furnace that performs partial combustion and / or pyrolysis.   A low-flow-type spouted bed furnace is provided with a downward fluidizing agent port at the bottom, and an air storage chamber is connected to the fluidizing agent port. The gasifier according to claim 1, further comprising means for supplying at least one of gas, air, water vapor and oxygen generated in a furnace.   The gasifier according to claim 1 or 2, wherein a bottom portion of the low flow velocity type entrained bed furnace has an upwardly expanding taper shape extending upward from the fluidizing agent port. Means for discharging gas from the low-flow-rate spouted bed furnace, means for recovering drain contained in the gas discharged from the low-flow-rate spouted bed furnace, means for spraying the recovered drain into the low-flow-rate spouted bed furnace, The gasifier according to claim 1, comprising:

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