JP2019178188A - Biomass carbide production system - Google Patents

Abstract

To provide a biomass carbide production system capable of suppressing generation of dioxin and improving energy saving while maintaining temperature of a dry processing part and a carbonization part.SOLUTION: A biomass carbide production system comprises: a first hot wind generation part 4 for generating hot wind G4 and supplying the hot wind G4 to one side of a dry processing part and a carbonization part; a second hot wind generation part 3 for generating the hot wind G4 and supplying the hot wind G3 to the other of the dry processing part and the carbonization part. In the biomass carbide production system, heat generated on a pyrolysis gas incineration part 5 is supplied to the first hot wind generation part 4, the second hot wind generation part 3 has a biomass burner Bv for taking out a part of dry biomass X2 generated on the dry processing part 1 as a solid biomass fuel and burning the same.SELECTED DRAWING: Figure 1

Description

  The present invention is generated in a drying processing unit that dries hydrated biomass to generate dry biomass, a carbonization processing unit that carbonizes dry biomass generated in the drying processing unit to generate biomass carbide, and is generated in the carbonization processing unit. The present invention relates to a biomass carbide manufacturing system including a pyrolysis gas incineration unit that incinerates a pyrolysis gas.

2. Description of the Related Art Conventionally, there is known a biomass carbide manufacturing system that manufactures biomass carbide by carbonizing after drying hydrous biomass such as dewatered sludge (see, for example, Patent Document 1). Such a biomass carbide manufacturing system can reduce the emission of greenhouse gases because it can omit the incineration of biomass waste and can use the manufactured biomass carbide as an alternative fuel for a thermal power plant. It is attracting attention as.
Moreover, in the biomass carbide manufacturing system described in Patent Document 1, a hot air generation unit (sludge incinerator 70) that generates hot air used as a heat source in the drying processing unit and the carbonization processing unit is provided. The hot air generated by the hot air generating unit is supplied in series to the carbonization processing unit and the drying processing unit. In addition, hydrous biomass and dry biomass are used as the fuel to be burned in the hot air generator.

JP 2005-319374 A

  In the biomass carbide manufacturing system described in Patent Document 1, it is necessary to set the temperature of the hot air generated in the hot air generation unit to a relatively high temperature in accordance with the processing temperature in the carbonization processing unit supplied first. Furthermore, in order to supply sufficient heat to the drying processing unit supplied next to the carbonization processing unit, it is necessary to generate a sufficient amount of hot air in the hot air generation unit. That is, in the hot air generating part of this biomass carbide manufacturing system, it is necessary to generate a relatively large amount of hot air at a relatively high temperature, and the consumption of fuel such as hydrous biomass is increased, resulting in a deterioration in energy saving. was there.

  Further, in this biomass carbide manufacturing system, the hot air generated by the hot air generating unit is configured to be supplied in series to the carbonizing unit and the drying unit, and after passing through the carbonizing unit on the front stage side, the latter stage Since the temperature of the hot air supplied to the drying processing unit on the side fluctuates depending on the state of the carbonization processing unit, even if the amount of combustion in the hot air generation unit is adjusted, the drying processing on the rear stage side It was difficult to maintain the part at an appropriate temperature.

  In view of this situation, the main problem of the present invention is that in a biomass carbide manufacturing system including a drying processing unit, a carbonization processing unit, and a pyrolysis gas incineration unit, while maintaining the drying processing unit and the carbonization processing unit at an appropriate temperature, saving The point is to provide a technique for improving energy.

The first characteristic configuration of the present invention is a drying treatment unit that dries hydrous biomass to produce dry biomass;
A carbonization processing unit that carbonizes the dry biomass generated in the drying processing unit to generate biomass carbide, and
A pyrolysis gas incineration unit for incinerating pyrolysis gas generated in the carbonization unit,
A first hot air generating unit that burns fuel to generate hot air and supplies the hot air to one of the drying processing unit and the carbonization processing unit;
A biomass carbide manufacturing system comprising: a second hot air generating unit that burns fuel to generate hot air and supplies the hot air to the other side of the drying processing unit and the carbonization processing unit;
The heat generated in the pyrolysis gas incinerator is supplied to the first hot air generator,
The second hot air generating unit has a biomass burner that takes out a part of the dried biomass generated in the drying processing unit as a solid biomass fuel and burns it.

According to this configuration, the hot air is supplied to the drying processing unit and the carbonization processing unit by the first hot air generation unit and the second hot air generation unit, respectively. Therefore, each of the drying treatment unit and the carbonization treatment unit can be maintained at an appropriate temperature in a form in which the amount of combustion in each hot air generation unit is adjusted.
And in a 2nd hot air generation | occurrence | production part, it has a biomass burner which takes out and burns a part of dry biomass produced | generated in the drying process part as solid biomass fuel. Therefore, in this 2nd hot air generation | occurrence | production part, in order to obtain the hot air of desired temperature, the fossil fuel which should be replenished separately from the said solid biomass fuel can be reduced.
On the other hand, in the first hot air generating unit, the fossil to be replenished separately from the heat generated in the pyrolysis gas incineration unit to obtain hot air at a desired temperature by supplying heat generated in the pyrolysis gas incineration unit. Fuel can be reduced.
Therefore, according to the present invention, in a biomass carbide production system including a drying processing unit, a carbonization processing unit, and a pyrolysis gas incineration unit, a technique for improving energy saving while maintaining the drying processing unit and the carbonization processing unit at an appropriate temperature. Can be provided.

The second characteristic configuration of the present invention is a low temperature hot air generating unit in which the first hot air generating unit generates low temperature hot air,
The second hot air generator is a high temperature hot air generator that generates high temperature hot air that is hotter than the low temperature hot air.

  According to this configuration, the high temperature hot air generating unit that supplies the high temperature hot air to the high temperature side processing unit whose processing temperature is higher than the other of the drying processing unit and the carbonization processing unit is generated in the drying processing unit. A biomass burner for taking out and burning a part of the dried biomass as solid biomass fuel is provided. Therefore, in this high-temperature hot air generator, dry biomass can be burned at a sufficiently high combustion temperature, so that generation of dioxins resulting from the combustion of the dry biomass can be suppressed, and high-temperature hot air at a desired temperature can be generated. It is possible to reduce the fossil fuel to be replenished separately from the solid biomass fuel.

  On the other hand, in the low temperature hot air generating unit that supplies the low temperature hot air to the low temperature side processing unit whose processing temperature is lower than the other of the drying processing unit and the carbonization processing unit, the low temperature hot air is lower in temperature than the high temperature hot air. Therefore, by supplying the heat generated in the pyrolysis gas incinerator, fossil fuel to be replenished separately from the heat generated in the pyrolysis gas incinerator to obtain the low temperature hot air at the desired temperature is reduced. be able to.

  The third characteristic configuration of the present invention is that the first hot air generating section is the pyrolysis gas incineration section.

  According to this configuration, the first hot air generation unit and the pyrolysis gas incineration unit can be configured by a single incinerator or the like. That is, the first hot air generating unit also functions as a pyrolysis gas incineration unit that incinerates the pyrolysis gas generated in the carbonization processing unit. Thus, in the first hot air generating unit, the pyrolysis gas generated in the carbonization processing unit is incinerated, so that the relatively high temperature exhaust gas generated by the incineration is directly used as hot air without lowering the temperature. It will be supplied to the processing unit or the carbonization processing unit. Therefore, the fossil fuel which should be replenished in order to obtain the hot air of desired temperature in a 1st hot air generation part can be reduced further.

  A fourth characteristic configuration of the present invention includes an air preheating unit that preheats combustion air supplied to the first hot air generation unit and the second hot air generation unit by heat exchange with exhaust gas discharged to the outside. It is in the point.

  According to this configuration, the exhaust gas generated in the pyrolysis gas incineration unit, the exhaust gas generated in the drying processing unit and the carbonization processing unit, hot air, etc. are partly or entirely discharged as exhaust gas to the outside such as the atmosphere. The heat stored in the exhaust gas discharged to the outside can be recovered by using the air preheating unit for preheating combustion air supplied to the first hot air generating unit and the second hot air generating unit. The energy saving property can be further improved.

  According to a fifth characteristic configuration of the present invention, each of the first hot air generator and the second hot air generator generates a fossil fuel burner for burning fossil fuel, and a combustion amount adjustment capable of adjusting a combustion amount by the fossil fuel burner. And means.

  According to this configuration, the first hot air generating unit and the second hot air generating unit are provided with the fossil fuel burner whose combustion amount can be adjusted by the combustion amount adjusting means, so that the fossil fuel in the fossil fuel burner can be adjusted. Hot air at a desired temperature can be secured by adjusting the combustion amount of the fossil fuel burner while keeping the combustion amount to a minimum.

Schematic configuration diagram of biomass carbide manufacturing system of the first embodiment Schematic configuration diagram of biomass carbide manufacturing system of the second embodiment Schematic block diagram of biomass carbide manufacturing system of the third embodiment Schematic configuration diagram of biomass carbide manufacturing system of the fourth embodiment Schematic configuration diagram of biomass carbide manufacturing system of the fifth embodiment Schematic configuration diagram of biomass carbide manufacturing system of sixth embodiment Diagram showing detailed configuration of distribution unit

  EMBODIMENT OF THE INVENTION Embodiment of the biomass carbide manufacturing system which concerns on this invention is described based on drawing. 1 to 6 show a schematic configuration of the biomass carbide production system in each of the first to sixth embodiments.

[Common configuration]
First, a common detailed configuration in the biomass carbide manufacturing system (hereinafter, also referred to as “the present system”) of each embodiment shown in FIGS. 1 to 6 will be described below.
In this system, a dry processing unit 1 that dries water-containing biomass X1 appropriately dehydrated by a dehydrator or the like to generate dry biomass X2, and a dry biomass X2 supplied from the drying processing unit 1 is carbonized to generate biomass carbide X3. Are provided, and a pyrolysis gas incineration unit 5 that incinerates the pyrolysis gas G2 generated in the carbonization processing unit 2 is provided.

Further, the present system includes a low temperature hot air generator 4 (an example of a first hot air generator) that burns fuel to generate a low temperature hot air G4 (an example of hot air), and a high temperature hot air G3 (an example of hot air) that burns fuel. A high-temperature hot-air generator 3 (an example of a second hot-air generator) that generates (an example). The system also includes an air preheating unit 8 that preheats the combustion air A supplied by the blower 9 by heat exchange with exhaust gas discharged to the atmosphere (an example of the outside), and heat recovery for recovering heat. Various facilities such as a heat exchanger 7 and a control device 50 for controlling operation are provided.
Hereinafter, the detailed configurations of the facilities provided in these systems will be described in order.

(Dry processing part)
The drying processing unit 1 is composed of, for example, a known hot air dryer or the like, and is supplied with water-containing biomass X1 dehydrated by a dehydration apparatus (not shown) as appropriate, and is supplied while stirring the supplied water-containing biomass X1. It is comprised so that it may be made to contact directly with the hot air of about 750 degreeC-850 degreeC made and dried. Therefore, from the drying processing unit 1, the dried biomass X2 after drying is discharged, and the exhaust gas G1 at about 150 ° C. to 250 ° C. including the moisture released from the water-containing biomass X1 is discharged.
The dried biomass X2 dispensed from the drying processing unit 1 is appropriately granulated and then supplied to the carbonization processing unit 2 described later.

(Carbonizing part)
The carbonization processing unit 2 is composed of, for example, a known indirect heating type rotary kiln and the like. The dried dry biomass X2 supplied from the drying processing unit 1 is input, and the input dry biomass X2 is low while stirring. It is configured to be heated and carbonized indirectly in an oxygen atmosphere. Therefore, from the carbonization processing unit 2, the carbonized biomass X3 is discharged, and the pyrolysis gas G2 including a combustible gas generated during the pyrolysis of the dry biomass X2 is discharged.
The biomass carbide X3 delivered from the carbonization processing unit 2 is delivered as a product after being cooled by, for example, a cooling conveyor.
On the other hand, the pyrolysis gas G2 discharged from the carbonization processing unit 2 is supplied to the pyrolysis gas incineration unit 5 described later.

  The carbonization processing unit 2 is provided with a heater 2a for indirectly heating the dry biomass X2 by heat exchange with hot air passing through the inside. And after the hot air supplied to the heater 2a of the carbonization process part 2 passes the said heater 2a and temperature falls, it is discharged | emitted from the heater 2a as waste gas G2a.

  The carbonization processing unit 2 will be described in detail later, but a relatively high temperature hot air of about 800 ° C. to 1000 ° C. is supplied to the heater 2a and carbonization is performed within a medium temperature to high temperature processing temperature range. (See FIG. 2, FIG. 3 and FIG. 4), or a heater having a relatively low temperature hot air of about 500 ° C. to 700 ° C. supplied to the heater 2a to perform carbonization within a low processing temperature range ( FIG. 1, FIG. 5 and FIG. 6).

(Pyrolysis gas incineration unit)
The pyrolysis gas incineration unit 5 is composed of, for example, a known gas combustion furnace, and completely burns the pyrolysis gas G2 supplied from the carbonization processing unit 2 while mixing and stirring with the combustion air A in a high temperature environment. It is configured to be incinerated. Therefore, in this pyrolysis gas incinerator 5, the exhaust gas G5 of about 800 ° C. to 900 ° C. including the exhaust gas of the pyrolysis gas G2 is generated.

(Low temperature hot air generator)
The low temperature hot air generating unit 4 is constituted by, for example, a known hot air generating furnace or the like, and is configured to generate combustion exhaust gas generated by burning fuel as low temperature hot air G4. The low-temperature hot air generator 4 is supplied with heat generated in the pyrolysis gas incinerator 5.
That is, in the low temperature hot air generation part 4, the heat generated in the pyrolysis gas incineration part 5 is added to the combustion exhaust gas generated by the fossil fuel burner Bf to generate the low temperature hot air G4.
Therefore, in this low temperature hot air generating unit 4, a relatively high temperature heat is supplied from the pyrolysis gas incineration unit 5 to generate the low temperature hot air G 4, thereby fossil to be replenished in order to obtain the low temperature hot air G 4 of the desired temperature. Fuel F is reduced.

The low-temperature hot-air generating unit 4 adjusts the amount of fossil fuel F supplied to the fossil fuel burner Bf and adjusts the combustion amount by the fossil fuel burner Bf (an example of combustion amount adjusting means). ) Is provided. For example, the control device 50 adjusts the combustion amount by the fossil fuel burner Bf by controlling the combustion amount adjustment valve 15 while confirming the furnace temperature and the temperature of the generated low temperature hot air G4, thereby generating the low temperature hot air generation unit 4. The temperature of the low-temperature hot air G4 to be maintained can be maintained at a desired temperature.
The low temperature hot air G4 generated by the low temperature hot air generation unit 4 is supplied to the low temperature side processing unit LP on the side of the drying processing unit 1 and the carbonization processing unit 2 where the processing temperature is low.

(High temperature hot air generator)
The high temperature hot air generating unit 3 is constituted by, for example, a known hot air generating furnace, and is configured to generate combustion exhaust gas generated by burning fuel as high temperature hot air G3 having a temperature higher than that of the low temperature hot air G4. Yes.
The high temperature hot air generating unit 3 is provided with a fossil fuel burner Bf for burning the fossil fuel F and a biomass burner Bv for burning a part of the dry biomass X2 taken out from the distribution unit 20 as solid biomass fuel.
That is, in the high temperature hot air generating unit 3, a mixed gas of the combustion exhaust gas generated by the fossil fuel burner Bf and the combustion exhaust gas generated by the biomass burner Bv is generated as the high temperature hot air G3.
Therefore, in this high-temperature hot-air generating unit 3, since the dried biomass X2 can be burned at a sufficiently high combustion temperature, the production of dioxins resulting from the combustion of the dried biomass X2 is suppressed, and further, desired The fossil fuel F to be replenished to obtain the high temperature hot air G3 is reduced.

The high-temperature hot-air generating unit 3 is configured to adjust the amount of fossil fuel F supplied to the fossil fuel burner Bf and to adjust the amount of combustion by the fossil fuel burner Bf (an example of combustion amount adjusting means). ) Is provided. For example, the control device 50 adjusts the combustion amount by the fossil fuel burner Bf by controlling the combustion amount adjustment valve 15 while confirming the furnace temperature and the temperature of the generated hot hot air G3. The temperature of the high-temperature hot air G3 to be maintained can be maintained at a desired temperature.
The high temperature hot air G3 generated by the high temperature hot air generation unit 3 is supplied to the high temperature side processing unit HP on the higher processing temperature side of the drying processing unit 1 and the carbonization processing unit 2.

(Air preheating part)
The air preheating unit 8 is composed of a low temperature hot air generating unit 4, a high temperature hot air generating unit 3, and a pyrolysis gas incineration unit by heat exchange with a relatively high temperature exhaust gas discharged to the atmosphere through the exhaust gas processing unit 10 and the chimney 12. 5 is configured as a gas-gas type heat exchanger for preheating the combustion air A supplied to 5.
That is, at least a part of the heat held by the exhaust gas discharged to the atmosphere or the like is used for preheating the combustion air A supplied to the low temperature hot air generating unit 4 and the high temperature hot air generating unit 3 by the air preheating unit 8. As a result of the recovery, further energy saving is improved.

(Heat exchange part for heat recovery)
In addition to the air preheating unit 8, a heat recovery heat exchanging unit 7 is provided for recovering heat from the exhaust gas discharged to the atmosphere or the like. The heat recovery heat exchanging unit 7 heats the exhaust gas supplied to the high temperature hot air generating unit 3 or the low temperature hot air generating unit 4 by heat exchange with the exhaust gas discharged to the atmosphere through the exhaust gas processing unit 10 and the chimney 12. It is configured as a gas-gas type heat exchanger.
That is, at least a part of the heat held by the exhaust gas discharged to the atmosphere or the like is recovered for heating the exhaust gas supplied to the high temperature hot air generating unit 3 or the low temperature hot air generating unit 4 to obtain the high temperature hot air G3 or the low temperature hot air G4. As a result, energy saving is further improved.

(Distributor)
The distribution unit 20 that takes out a part of the dried biomass X2 generated by the drying processing unit 1 and supplies it to the biomass burner Bv can be configured as shown in FIG.
That is, the distribution unit 20 is provided with a distribution unit buffer tank 21, a combustion unit buffer tank 22, and a carbonization processing unit buffer tank 23. That is, in the carbonization processing unit 2, by maintaining the supply amount of the dry biomass X2 at the set supply amount, the dry biomass X2 is carbonized under stable processing conditions, and the high quality biomass carbide X3 having a stable quality is obtained. Is generated.

The distribution unit buffer tank 21 is configured to temporarily store the dry biomass X2 in the distribution unit 20 that distributes the dry biomass X2 generated in the dry processing unit 1 to the biomass burner Bv side and the carbonization processing unit 2 side. Has been.
The combustion unit buffer tank 22 is configured to temporarily store the dry biomass X2 in a path from the distribution unit 20 to the biomass burner Bv.
The carbonization processing unit buffer tank 23 is configured to temporarily store the dry biomass X2 in a path leading from the distribution unit 20 to the carbonization processing unit 2.

  In the present embodiment, the distribution unit 20 is provided with three buffer tanks 21, 22, and 23 including a distribution unit buffer tank 21, a combustion unit buffer tank 22, and a carbonization processing unit buffer tank 23. However, only the distribution part buffer tank 21 can be provided, or one of the combustion part buffer tank 22 and the carbonization part buffer tank 23 can be omitted. That is, by providing at least the distribution unit buffer tank 21 as the dry biomass storage means, it is possible to stabilize the processing conditions of the carbonization processing unit 2 and generate high quality biomass carbide X3.

  Each buffer tank 21, 22, 23 is provided with feeders 21a, 21b, 22a, 23a for discharging the stored dry biomass X2 to the supply destination. These feeders 21a, 21b, 22a, and 23a are controlled by a control device 50 (see FIGS. 1 to 6) so that the amount of dry biomass X2 discharged from each of the buffer tanks 21, 22, and 23 can be adjusted. ing.

  That is, the dry biomass X <b> 2 generated by the drying processing unit 1 is temporarily stored in the distribution unit buffer tank 21. Then, the dry biomass X2 paid out from the distribution unit buffer tank 21 by the feeder 21a is temporarily stored in the combustion unit buffer tank 22, and the stored dry biomass X2 is paid out by the feeder 22a to be solid biomass. The fuel is supplied to the biomass burner Bv as fuel.

  On the other hand, the dry biomass X2 discharged from the distribution unit buffer tank 21 by the feeder 21b is temporarily stored in the carbonization processing unit buffer tank 23, and the stored dry biomass X2 is discharged by the feeder 23a and carbonized. It is supplied to the carbonization processing unit 2 as a processing target.

[First Embodiment]
Next, a detailed configuration of the system of the first embodiment shown in FIG. 1 will be described.
The high temperature hot air generating unit 3 is configured to generate a high temperature hot air G3 of about 750 ° C to 850 ° C. On the other hand, the low temperature hot air generating unit 4 is configured to generate a low temperature hot air G4 having a temperature lower than that of the high temperature hot air G3, which is about 500 ° C. to 700 ° C. And the drying process part 1 is comprised as the high temperature side process part HP to which the high temperature hot air G3 which the high temperature hot air generation part 3 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a low temperature side processing unit LP to which the low temperature hot air G4 generated by the low temperature hot air generation unit 4 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odorous gas, it is returned to the high-temperature hot air generating unit 3 to incinerate the dust and odorous gas contained therein.
On the other hand, the low temperature hot air G4 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 200 ° C to 400 ° C. The exhaust gas G2a discharged from the heater 2a is mainly returned to the low-temperature hot air generation unit 4, but some of the exhaust gas G2a is supplied to the chimney 12 and used as a dilution exhaust gas for white smoke prevention. Etc. are discharged.

  A pyrolysis gas incineration unit 5 is provided separately from the high temperature hot air generation unit 3 and the low temperature hot air generation unit 4. The combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generation unit 3, the low temperature hot air generation unit 4, and the pyrolysis gas incineration unit 5.

A part of the exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 is taken out and supplied to the low temperature hot air generation unit 4. Thus, the heat generated in the pyrolysis gas incineration unit 5 is supplied to the low temperature hot air generation unit 4.
On the other hand, the remainder of the exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 that is not supplied to the low temperature hot air generation unit 4 is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.

Further, a part of the high temperature hot air G3 generated by the high temperature hot air generating unit 3 is taken out and discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12 and the like, similar to the exhaust gas G5.
Specifically, a part of the exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 and a part of the high temperature hot air G3 generated in the high temperature hot air generation unit 3 are mixed, and the mixed gas is discharged as exhaust gas G20 to the atmosphere or the like. Is done.

A heat exchanging heat exchanging portion 7 and an air preheating portion 8 are sequentially arranged in series along the flow direction of the exhaust gas G20.
And in the heat exchange part 7 for heat recovery of the front | former stage side, the waste gas G1 returned to the high temperature hot air generation part 3 is heated by heat exchange with the comparatively high temperature waste gas G20. In the air preheating unit 8 on the rear stage side, the combustion air A is preheated by heat exchange with the exhaust gas G20 that has passed through the heat recovery heat exchanging unit 7 and has been slightly lowered in temperature.

  In the present embodiment, a part of the high temperature hot air G3 generated by the high temperature hot air generator 3 is taken out and discharged to the atmosphere as the exhaust gas G20. However, as shown by a one-dot chain line in FIG. A part of the exhaust gas G1 discharged from the section 1 can be taken out and discharged to the atmosphere or the like. In this case, the exhaust gas G1 taken out is supplied to the pyrolysis gas incineration unit 5 so that the dust and odor gas contained in the exhaust gas G1 are incinerated.

[Second Embodiment]
Next, the detailed structure of this system of 2nd Embodiment shown in FIG. 2 is demonstrated.
The high temperature hot air generator 3 is configured to generate a high temperature hot air G3 of about 800 ° C to 1000 ° C. On the other hand, the low temperature hot air generating unit 4 is configured to generate a low temperature hot air G4 having a temperature of about 750 ° C. to 850 ° C. that is lower than the high temperature hot air G3. And the drying process part 1 is comprised as the low temperature side process part LP to which the low temperature hot air G4 which the low temperature hot air generation part 4 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a high temperature side processing unit HP to which the high temperature hot air G3 generated by the high temperature hot air generation unit 3 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odor gas, the exhaust gas G1 is returned to the low-temperature hot air generation unit 4 to incinerate the dust and odor gas contained therein.
On the other hand, the high temperature hot air G3 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 500 ° C. to 700 ° C., and at least a part is returned to the high temperature hot air generating unit 3. It is.

  A pyrolysis gas incineration unit 5 is provided separately from the high temperature hot air generation unit 3 and the low temperature hot air generation unit 4. The combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generation unit 3, the low temperature hot air generation unit 4, and the pyrolysis gas incineration unit 5.

The exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 is entirely supplied to the low temperature hot air generation unit 4. Thus, the heat generated in the pyrolysis gas incineration unit 5 is supplied to the low temperature hot air generation unit 4.
A part of the exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 is taken out and returned to the high temperature hot air generating unit 3, but the remaining part is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.
A part of the low temperature hot air G4 generated by the low temperature hot air generating unit 4 is taken out and discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.

In the heat recovery heat exchanger 7, the exhaust gas G1 returned to the low temperature hot air generator 4 is heated by heat exchange with the relatively high temperature low temperature hot air G4 discharged from the low temperature hot air generator 4 to the atmosphere or the like.
On the other hand, in the air preheating unit 8, the combustion air A is preheated by heat exchange with the relatively high temperature exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 to the atmosphere or the like.

[Third Embodiment]
Next, the detailed structure of this system of 3rd Embodiment shown in FIG. 3 is demonstrated.
The high temperature hot air generator 3 is configured to generate a high temperature hot air G3 of about 800 ° C to 1000 ° C. On the other hand, the low temperature hot air generating unit 4 is configured to generate a low temperature hot air G4 having a temperature of about 750 ° C. to 850 ° C. that is lower than the high temperature hot air G3. And the drying process part 1 is comprised as the low temperature side process part LP to which the low temperature hot air G4 which the low temperature hot air generation part 4 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a high temperature side processing unit HP to which the high temperature hot air G3 generated by the high temperature hot air generation unit 3 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odor gas, the exhaust gas G1 is returned to the low-temperature hot air generation unit 4 to incinerate the dust and odor gas contained therein.
On the other hand, the high temperature hot air G3 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 500 ° C. to 700 ° C., and at least a part is returned to the high temperature hot air generating unit 3. It is.

  A pyrolysis gas incineration unit 5 is provided separately from the high temperature hot air generation unit 3 and the low temperature hot air generation unit 4. A part of the combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generating unit 3 and the pyrolysis gas incineration unit 5. On the other hand, the remaining portion of the combustion air A preheated by the air preheating unit 8 is heated to a higher temperature by the heat recovery heat exchange unit 7 and then supplied to the low temperature hot air generating unit 4.

A part of the exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 is taken out and supplied to the low temperature hot air generation unit 4. Thereby, the heat generated in the pyrolysis gas incineration unit 5 is supplied to the low temperature hot air generation unit 4.
On the other hand, the remaining portion of the exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 that is not supplied to the low temperature hot air generation unit 4 is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.
A part of the exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 is taken out and returned to the high temperature hot air generating unit 3, but the remaining part is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.

In the heat recovery heat exchanger 7, the combustion air A supplied to the low temperature hot air generator 4 is preheated by heat exchange with the relatively high temperature exhaust gas G5 discharged from the pyrolysis gas incinerator 5 to the atmosphere or the like. The Thus, the heat generated in the pyrolysis gas incineration unit 5 is supplied to the low temperature hot air generation unit 4.
On the other hand, the air preheating unit 8 distributes and supplies the heat to the high temperature hot air generating unit 3 and the pyrolysis gas incineration unit 5 by heat exchange with the relatively high temperature exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 to the atmosphere or the like. Combustion air A is preheated.

  A part of the exhaust gas G1 discharged from the drying processing unit 1 is supplied to the low temperature hot air generating unit 4, but the remaining part is taken out and discharged to the atmosphere or the like. In this case, the exhaust gas G1 taken out is supplied to the pyrolysis gas incineration unit 5 so that the dust and odor gas contained in the exhaust gas G1 are incinerated. It should be noted that a part of the low temperature hot air G4 generated by the low temperature hot air generation unit 4 may be discharged to the atmosphere instead of discharging a part of the exhaust gas G1 discharged from the drying processing unit 1 to the atmosphere or the like. In this case, the low temperature hot air G4 discharged to the atmosphere or the like is subjected to incineration processing of odor gas or the like in the low temperature hot air generation unit 4, and thus is not supplied to the pyrolysis gas incineration unit 5 and is appropriately treated as exhaust gas. May be discharged to the atmosphere or the like.

[Fourth Embodiment]
Next, a detailed configuration of the system of the fourth embodiment shown in FIG. 4 will be described.
The high temperature hot air generator 3 is configured to generate a high temperature hot air G3 of about 800 ° C to 1000 ° C. On the other hand, the low temperature hot air generating unit 4 is configured to generate a low temperature hot air G4 having a temperature of about 750 ° C. to 850 ° C. that is lower than the high temperature hot air G3. And the drying process part 1 is comprised as the low temperature side process part LP to which the low temperature hot air G4 which the low temperature hot air generation part 4 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a high temperature side processing unit HP to which the high temperature hot air G3 generated by the high temperature hot air generation unit 3 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odor gas, the exhaust gas G1 is returned to the low-temperature hot air generation unit 4 to incinerate the dust and odor gas contained therein.
On the other hand, the high temperature hot air G3 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 500 ° C. to 700 ° C., and at least a part is returned to the high temperature hot air generating unit 3. It is.

  A pyrolysis gas incineration unit 5 is provided separately from the high temperature hot air generation unit 3 and the low temperature hot air generation unit 4. The combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generation unit 3, the low temperature hot air generation unit 4, and the pyrolysis gas incineration unit 5.

The exhaust gas G5 discharged from the pyrolysis gas incineration unit 5 is entirely discharged to the atmosphere through the exhaust gas processing unit 10, the chimney 12, and the like.
A part of the exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 is taken out and returned to the high temperature hot air generating unit 3, but the remaining part is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.

In the heat recovery heat exchanger 7, the exhaust gas G1 returned to the low temperature hot air generator 4 is heated by heat exchange with the relatively high temperature exhaust gas G5 discharged from the pyrolysis gas incinerator 5 to the atmosphere or the like. Thus, the heat generated in the pyrolysis gas incineration unit 5 is supplied to the low temperature hot air generation unit 4.
On the other hand, in the air preheating unit 8, the combustion air A is preheated by heat exchange with the relatively high temperature exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 to the atmosphere or the like.

  A part of the exhaust gas G1 discharged from the drying processing unit 1 is supplied to the low temperature hot air generating unit 4, but the remaining part is taken out and discharged to the atmosphere or the like. In this case, the exhaust gas G1 taken out is supplied to the pyrolysis gas incineration unit 5 so that the dust and odor gas contained in the exhaust gas G1 are incinerated. It should be noted that a part of the low temperature hot air G4 generated by the low temperature hot air generation unit 4 may be discharged to the atmosphere instead of discharging a part of the exhaust gas G1 discharged from the drying processing unit 1 to the atmosphere or the like. In this case, in the low temperature hot air G4 discharged to the atmosphere or the like, the low temperature hot air generating unit 4 is subjected to incineration processing of odor gas or the like, so that the exhaust gas processing is appropriately performed as it is without being supplied to the pyrolysis gas incineration unit 5. May be discharged to the atmosphere or the like.

[Fifth Embodiment]
Next, the detailed structure of this system of 5th Embodiment shown in FIG. 5 is demonstrated.
This system is provided with a low temperature hot air generator 11 that functions as the low temperature hot air generator 4 that generates the low temperature hot air G4 and also functions as the pyrolysis gas incinerator 5.
That is, the low temperature hot air generating unit 11 functions as the low temperature hot air generating unit 4 that generates the low temperature hot air G4 of about 500 ° C. to 700 ° C. Furthermore, the low temperature hot air generating unit 11 also functions as the pyrolysis gas incineration unit 5 that incinerates the pyrolysis gas G2 supplied from the carbonization processing unit 2 by completely combusting it while mixing with the combustion air A in a high temperature environment. To do. That is, in such a low temperature hot air generating unit 11, the heat generated by incinerating the pyrolysis gas G2 is used for heating the low temperature hot air G4, and the heat generated in the pyrolysis gas incineration unit 5 is low temperature hot air. It is supplied to the generator 4.
Moreover, in such a low temperature hot air generation part 11, about 850 degreeC and comparatively high temperature waste gas G11 generate | occur | produces, The one part is mixed with the comparatively low temperature waste gas G2a discharged | emitted from the heater 2a, and low temperature of suitable temperature. Hot air G4 is generated, and the remaining exhaust gas G11 is discharged to the atmosphere or the like.
In the present embodiment, the low temperature hot air generator 11 is configured to mix the relatively high temperature exhaust gas G11 with the relatively low temperature exhaust gas G2a to generate the low temperature hot air G4 supplied to the heater 2a. However, when the exhaust gas G11 is at a relatively low temperature, the exhaust gas G11 may be supplied to the heater 2a as the low-temperature hot air G4 without mixing the exhaust gas G2a.

  The high temperature hot air generating unit 3 is configured to generate a high temperature hot air G3 of about 750 ° C. to 850 ° C. that is higher than the low temperature hot air G4. And the drying process part 1 is comprised as the high temperature side process part HP to which the high temperature hot air G3 which the high temperature hot air generation part 3 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a low temperature side processing unit LP to which the low temperature hot air G4 generated by the low temperature hot air generation unit 11 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odorous gas, it is returned to the high-temperature hot air generating unit 3 to incinerate the dust and odorous gas contained therein.
On the other hand, the low temperature hot air G4 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 200 ° C to 400 ° C. The exhaust gas G2a discharged from the heater 2a is mainly returned to the low-temperature hot air generating unit 11, but some of the exhaust gas G2a is supplied to the chimney 12 and used as dilution exhaust gas for white smoke prevention. Etc. are discharged.

  The combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generating unit 3 and the low temperature hot air generating unit 11.

The exhaust gas G11 discharged from the low temperature hot air generating unit 11 is entirely discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.
Further, a part of the high temperature hot air G3 generated by the high temperature hot air generating unit 3 is taken out and discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12 and the like in the same manner as the exhaust gas G11.
Specifically, the exhaust gas G11 discharged from the low temperature hot air generator 11 and a part of the high temperature hot air G3 generated in the high temperature hot air generator 3 are mixed, and the mixed gas is discharged as the exhaust gas G20 to the atmosphere or the like.

A heat exchanging heat exchanging portion 7 and an air preheating portion 8 are sequentially arranged in series along the flow direction of the exhaust gas G20.
And in the heat exchange part 7 for heat recovery of the front | former stage side, the waste gas G1 returned to the high temperature hot air generation part 3 is heated by heat exchange with the comparatively high temperature waste gas G20. In the air preheating unit 8 on the rear stage side, the combustion air A is preheated by heat exchange with the exhaust gas G20 that has passed through the heat recovery heat exchanging unit 7 and has been slightly lowered in temperature.

  In the present embodiment, a part of the high temperature hot air G3 generated by the high temperature hot air generator 3 is taken out and discharged to the atmosphere as the exhaust gas G20. However, as shown by a one-dot chain line in FIG. A part of the exhaust gas G1 discharged from the section 1 can be taken out and discharged to the atmosphere or the like. In this case, the taken-out exhaust gas G1 is supplied to the low temperature hot air generating unit 11, whereby the dust and odor gas contained in the exhaust gas G1 are incinerated.

[Sixth Embodiment]
Next, a detailed configuration of the system of the sixth embodiment shown in FIG. 6 will be described.
This system is provided with a low temperature hot air generator 11 that functions as the low temperature hot air generator 4 that generates the low temperature hot air G4 and also functions as the pyrolysis gas incinerator 5.
That is, the low temperature hot air generating unit 11 functions as the low temperature hot air generating unit 4 that generates the low temperature hot air G4 of about 750 ° C. to 850 ° C. Furthermore, the low temperature hot air generating unit 11 also functions as the pyrolysis gas incineration unit 5 that incinerates the pyrolysis gas G2 supplied from the carbonization processing unit 2 by completely combusting it while mixing with the combustion air A in a high temperature environment. To do. That is, in the low temperature hot air generating unit 11, the heat generated by incinerating the pyrolysis gas G2 is used for heating the low temperature hot air G4, and the heat generated in the pyrolysis gas incineration unit 5 is the low temperature hot air generating unit. 4 is supplied.
Further, in such a low temperature hot air generating unit 11, a relatively high temperature exhaust gas G11 of about 850 ° C. is generated. A part of the exhaust gas G11 is mixed with a relatively low temperature exhaust gas G1 discharged from the drying processing unit 1 to obtain an appropriate temperature. Low-temperature hot air G4, and the remaining exhaust gas G11 is discharged to the atmosphere or the like.
In the present embodiment, the low temperature hot air generating unit 11 is configured to mix the relatively high temperature exhaust gas G11 with the relatively low temperature exhaust gas G1 to generate the low temperature hot air G4 supplied to the drying processing unit 1. However, when the exhaust gas G11 has a relatively low temperature, the exhaust gas G11 may be supplied to the drying processing unit 1 as the low temperature hot air G4 without mixing the exhaust gas G2a.

  The high-temperature hot air generating unit 3 is configured to generate a high-temperature hot air G3 having a temperature higher than that of the low-temperature hot air G4, which is about 800 ° C. to 1000 ° C. And the drying process part 1 is comprised as the low temperature side process part LP to which the low temperature hot air G4 which the low temperature hot air generation part 11 generate | occur | produced is supplied. On the other hand, the carbonization processing unit 2 is configured as a high temperature side processing unit HP to which the high temperature hot air G3 generated by the high temperature hot air generation unit 3 is supplied to the heater 2a.

Since the exhaust gas G1 discharged from the drying processing unit 1 contains biomass dust and odor gas, it is returned to the low-temperature hot air generation unit 11 to incinerate the dust and odor gas contained therein.
On the other hand, the high temperature hot air G3 after passing through the heater 2a of the carbonization processing unit 2 is discharged from the heater 2a as exhaust gas G2a in a state where the temperature is lowered to about 500 ° C. to 700 ° C., and at least a part is returned to the high temperature hot air generating unit 3. It is.

  The combustion air A preheated by the air preheating unit 8 is distributed and supplied to the high temperature hot air generating unit 3 and the low temperature hot air generating unit 11.

The exhaust gas G11 discharged from the low temperature hot air generating unit 11 is entirely discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.
A part of the exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 is taken out and returned to the high temperature hot air generating unit 3, but the remaining part is discharged to the atmosphere or the like through the exhaust gas processing unit 10, the chimney 12, and the like.

In the heat recovery heat exchanger 7, the exhaust gas G1 returned to the low temperature hot air generator 4 is heated by heat exchange with the relatively high temperature exhaust gas G11 discharged from the low temperature hot air generator 11 to the atmosphere or the like.
On the other hand, in the air preheating unit 8, the combustion air A is preheated by heat exchange with the relatively high temperature exhaust gas G2a discharged from the heater 2a of the carbonization processing unit 2 to the atmosphere or the like.

[Another embodiment]
Another embodiment of the present invention will be described. Note that the configuration of each embodiment described below is not limited to being applied alone, but may be applied in combination with the configuration of another embodiment.

(1) In the said embodiment, the air preheating part 8 which preheats the combustion air A supplied with respect to the low temperature hot air generation part 4 and the high temperature hot air generation part 3 by heat exchange with the waste gas discharged | emitted by the atmosphere etc. is provided. However, the installation location and presence / absence of installation of the air preheating unit 8 can be changed as appropriate.

(2) In the above embodiment, each of the low temperature hot air generating unit 4 and the high temperature hot air generating unit 3 is provided with the fossil fuel burner Bf and configured to burn the fossil fuel F in order to obtain hot air at a desired temperature. You may comprise so that a hot air of desired temperature may be obtained by replenishing heat with another form. In addition, when only the heat generated by the combustion of the biomass burner Bv and the heat generated in the pyrolysis gas incineration unit 5 can be supplied and hot air at a desired temperature can be obtained without supplementing other heat, The configuration for replenishing heat may be omitted.

(3) In the above embodiment, the low temperature hot air generating unit 4 is the first hot air generating unit to which the heat generated in the pyrolysis gas incineration unit 5 is supplied, and the high temperature hot air generating unit 3 is the second having the biomass burner Bv. Although the hot air generating unit is used, the low temperature hot air generating unit 4 may be provided with the biomass burner Bv and the heat generated in the pyrolysis gas incineration unit 5 may be supplied to the high temperature hot air generating unit 3.

DESCRIPTION OF SYMBOLS 1 Drying process part 2 Carbonization process part 3 High temperature hot air generation part (2nd hot air generation part)
4 Low temperature hot air generator (first hot air generator)
5 Pyrolysis gas incineration unit 8 Air preheating unit 11 Low temperature hot air generation unit 15 Combustion amount adjusting valve (combustion amount adjusting means)
A Combustion air Bf Fossil fuel burner Bv Biomass burner F Fossil fuel G2 Pyrolysis gas G3 Hot hot air (hot air)
G4 Low temperature hot air (hot air)
X1 Hydrous biomass X2 Dry biomass X3 Biomass carbide

Claims (5)

A drying treatment unit for drying the hydrous biomass to produce dry biomass;
A carbonization processing unit that carbonizes the dry biomass generated in the drying processing unit to generate biomass carbide, and
A pyrolysis gas incineration unit for incinerating pyrolysis gas generated in the carbonization unit,
A first hot air generating unit that burns fuel to generate hot air and supplies the hot air to one of the drying processing unit and the carbonization processing unit;
A biomass carbide manufacturing system comprising: a second hot air generating unit that burns fuel to generate hot air and supplies the hot air to the other side of the drying processing unit and the carbonization processing unit;
The heat generated in the pyrolysis gas incinerator is supplied to the first hot air generator,
The biomass carbide manufacturing system which has a biomass burner with which the 2nd hot air generating part takes out a part of dry biomass produced in the dry treating part as solid biomass fuel, and burns it. The first hot air generator is a low temperature hot air generator that generates low temperature hot air,
The biomass carbide manufacturing system according to claim 1, wherein the second hot air generating unit is a high temperature hot air generating unit that generates high temperature hot air having a temperature higher than that of the low temperature hot air.   The biomass carbide manufacturing system according to claim 1 or 2, wherein the first hot air generation unit is the pyrolysis gas incineration unit.   The air preheating part which preheats by the heat exchange with the waste gas discharged | emitted outside the combustion air supplied with respect to the said 1st hot air generation part and the said 2nd hot air generation part is provided. The biomass carbide manufacturing system according to item 1.   Each of the said 1st hot-air generation | occurrence | production part and the said 2nd hot-air generation | occurrence | production part has a fossil fuel burner which burns a fossil fuel, and the combustion amount adjustment means which can adjust the combustion amount by the said fossil fuel burner. The biomass carbide manufacturing system according to any one of the above.

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