JP4101699B2 - Biomass gasification system and biomass gasification method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a biomass gasification system and a biomass gasification method capable of effectively using biomass as a raw material and obtaining a clean gas raw material that can be used for fuel or for producing liquid fuel such as alcohol.
[0002]
[Background technology]
Biomass generally refers to organisms that can be used as energy sources or industrial raw materials (for example, agricultural products or by-products, wood, plants, etc.), and are produced by the action of solar energy, air, water, soil, etc. So it can be played indefinitely.
[0003]
By using the biomass, it is possible to produce a clean energy source such as fuel gas and methanol. In addition, because it can process biomass as waste, it is useful for environmental purification, and newly produced biomass can be converted into CO2 by photosynthesis. ₂ Because it grows by fixation of atmospheric CO ₂ Does not increase the CO ₂ This is a preferable technique because it leads to suppression of the problem.
[0004]
FIG. 8 shows an example of a conventional configuration of a biomass gasification system that uses such biomass to obtain a raw material gas, in which the obtained gas is converted into alcohol, which is a typical example of liquid fuel.
As shown in FIG. 8, biomass supply means 103 for supplying biomass 101 into the furnace body 102, and oxidant supply means for supplying combustion oxidant 104 made of oxygen or a mixture of oxygen and water vapor into the furnace body 102. 105, a biomass gasification furnace 106, a separation means 108 such as a cyclone for removing dust in the product gas 107 gasified by the biomass gasification furnace 106, and a cooler 109 for cooling the dust-removed gas Methanol from a gas purification device 110 that purifies the cooled gas, and a methanol synthesis device 114 that includes a distillation device 113 that synthesizes methanol using the purified gas and separates it into exhaust gas 111 and methanol 112. A synthesis system 112 is configured.
[0005]
As the biomass 101 to be supplied, it is preferable to supply pulverized and dried biomass produced or discarded. In the present invention, the biomass means a biological resource (for example, agricultural product or by-product, wood, plant, etc.) that can be used as an energy source or an industrial raw material. For example, sweet sorghum, napier grass, spirulina, etc. are used. (Patent Documents 1 and 2, Non-Patent Document 1).
[0006]
[Patent Document 1]
JP 2001-240877 A
[Patent Document 2]
JP 2001-240878 A
[Non-Patent Document 1]
Published by Masayasu Sakai, “21st Century Energy Opened by Biomass”, published by Morikita Publishing Co., Ltd., October 28, 1998
[0007]
[Problems to be solved by the invention]
The gas produced from the biomass as a raw material contains fine particles, tar components, hydrogen sulfide, chlorine, and the like, so as it is, a gas for synthesizing a liquid fuel using a synthesis catalyst and an energy source for a fuel cell. Not suitable for. Therefore, as described above, the gas purification device 110 including the separation device 108 is devised to remove trace components such as the fine particles, tar components, hydrogen sulfide, and chlorine. As a raw material gas for obtaining an energy source for the above-described liquid fuel and fuel cell, in actual operation, it is necessary to reduce the permissible content of the trace component to a detection limit amount. However, in the current biomass gasification system, the trace component has not been sufficiently reduced.
[0008]
Further, the processing scale by the biomass gasification system is several hundred tons / day, which corresponds to a small to medium-scale plant as compared with a conventional gasification system using fossil fuel. In such a small-medium scale gas processing system, it is desirable to provide a simple and inexpensive gas purification line, which is an essential condition in a so-called decentralized plant. Also in this regard, the current biomass gasification system has not yet achieved a simple and inexpensive purification line.
[0009]
When biomass is used as a gasification raw material, the supply of biomass from the biomass supply means 103 to the furnace body 102 is usually performed at normal pressure because it is difficult to seal this part of the line. Therefore, it is important not to cause a pressure loss as much as possible in the purification line for purifying the gas released from the gasification furnace. Regarding this point as well, in the current biomass gasification system, the reduction of pressure loss has not been sufficiently effective.
[0010]
If a filtration device that requires so-called backwashing, such as a bag filter, is used as a means for filtering dust from the product gas, pressure must be applied to the purification line in the direction opposite to the line flow during filter regeneration. The composition becomes unstable. For this reason, it is necessary to avoid the use of a filtration / separation apparatus that requires such backwashing as much as possible. Also in this regard, the current biomass gasification system is inadequate, and if it is attempted to thoroughly enforce this point, an alternative filtration separation means must be developed.
[0011]
The present invention has been made in view of the above circumstances, and high-precision purification of product gas can be realized at a low cost by a simple purification line configuration, reducing the pressure loss of the purification line, and backwashing the purification elements. It is an object of the present invention to provide a biomass gasification system and a biomass gasification method that do not need to be used.
[0012]
[Means for Solving the Problems]
The invention of [Claim 1] that solves the above-described problem is a biomass comprising a biomass gasification furnace that gasifies the supplied biomass and a gas purification line that purifies the gas generated in the biomass gasification furnace. A gasification system, wherein a biomass adsorption purification apparatus using biomass as an adsorbent is provided in the gas purification line. The biomass adsorption and purification apparatus includes a biomass adsorption tower in which biomass is filled and an introduction port for the produced gas and an exhaust port for the gas that has passed through the internal biomass are provided. An input means for supplying biomass, and a lower biomass discharge means provided at the lower part of the biomass adsorption tower and for discharging the lower biomass in the adsorption tower It is characterized by that. The biomass used as the adsorbent is characterized by being a gasification raw material itself.
[0014]
[Claims 2 The invention of claim 1 In the above, an upper biomass discharging means for discharging upper biomass in the adsorption tower is further provided at the upper part of the biomass adsorption tower.
[0015]
[Claims 3 The invention of claim 1 Or 2 In addition, a biomass stirring means for stirring the biomass in the adsorption tower is further provided.
[0016]
[Claims 4 The invention of claim 1 starts from claim 1. 3 One of One The method further comprises an adsorption biomass transfer means for transferring the adsorption biomass discharged from the biomass adsorption tower as a gasification biomass material to the biomass gasification furnace.
[0017]
[Claims 5 The invention of claim 1 starts from claim 1. 4 One of One In the gas purification line, a dust removing device using a water jet jet is further provided upstream of the biomass adsorption tower.
[0018]
[Claims 6 The invention of claim 5 In the above, the dust removing device using the water jet jet sucks the generated gas to form a water jet jet in the vertical axis direction, and the jet jet communicated with the drive nozzle and discharged from the drive nozzle The water jet jet and the generated gas are gas-liquid mixed by being received so as to cover, and a scrubber unit that performs dust removal of the generated gas, a circulating water tank that stores the water jet jet water as circulating water, and the circulating water A suction inner cylinder disposed in the tank, facing the opening of the scrubber outlet and having an opening having a weir around it, and a circulation in the suction inner cylinder disposed in the suction inner cylinder A discharge pipe for forcibly discharging water with a circulation pump and a strainer interposed in the discharge pipe are provided.
[0019]
[Claims 7 The invention of claim 6 The liquid level of the suction inner cylinder is always kept lower than the circulating water tank.
[0020]
[Claims 8 ] Is a biomass gasification method using biomass as fuel, supplying biomass and a combustion oxidant to a biomass gasification furnace and heating the interior of the furnace to a predetermined temperature to generate gas, Purify the product gas using at least biomass as an adsorbent The adsorbed biomass after use as the adsorbent is transferred to the biomass gasification furnace and used as a gasified biomass material, and the water jet jet is used as a pre-process of the adsorption step using the biomass adsorbent. Dust removal of generated gas It is characterized by that.
[0023]
In the present invention, the biomass used as the gasification raw material includes the above-mentioned narrowly defined “organism that can be used as an energy source or industrial raw material”, and further, as an alternative raw material thereof. This means a broad raw material that also contains usable organic waste.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
As described above, the biomass gasification system according to the present invention includes a biomass gasification furnace that gasifies the supplied biomass and a gas purification line that purifies the gas generated in the biomass gasification furnace. A biomass adsorption / purification apparatus using biomass as an adsorbent is provided in the gas purification line.
[0025]
Moreover, the biomass gasification method according to the present invention is a biomass gasification method using biomass as a fuel by supplying biomass and a combustion oxidant to a biomass gasification furnace and heating the inside of the furnace to a predetermined temperature. The gas is produced, and the produced gas is purified using at least biomass as an adsorbent.
[0026]
In the present invention, in the latter stage of the product gas purification line, although it does not reach the adsorption performance of activated carbon, the narrowly defined biomass that has practically effective adsorption characteristics and is inexpensive and can be used in large quantities is adsorbent. It is used as a main feature. By passing a large amount of pulverized biomass through the gas purified by the conventional dust removal and tar component separation device in the previous stage, fine dust, particulate tar, hydrogen sulfide that could not be reduced to the detection limit conventionally Further, trace components such as chlorine and formaldehyde can be reduced to a desired content of a detection limit amount. Moreover, since this biomass adsorbent can be sequentially replaced under normal pressure, the adsorption adsorbent approaches the adsorption limit, and the discharged biomass adsorbent can be transferred to a gasifier and effectively used as a gasified biomass material. This high-accuracy adsorption removal process can be operated at a very low cost. In addition, since the biomass adsorbent is porous and lightweight, the pressure loss generated when the gas is allowed to pass through the adsorption is very small. Although the biomass used as the adsorbent is a pulverized product, its particle size is better when considering only the improvement of adsorption performance. Alternatively, the case of handling as a fluidized bed must be considered, and a suitable particle size when reusing the adsorbed biomass as the gasification material after reaching the adsorption limit must be maintained, such as As a result of taking various conditions into consideration, a pulverized particle size equivalent to that of the gasification material is preferable. That is, a pulverized biomass having an average particle size adjusted to a range of 0.05 mm to 5 mm can be suitably used.
[0027]
In the biomass gasification system according to the present invention, the biomass adsorption and purification apparatus is filled with biomass and is provided with an inlet for the generated gas and an outlet for gas that has passed through the biomass in the interior. It is desirable to have an adsorption tower, an input means for introducing biomass into the biomass adsorption tower, and a lower biomass discharge means provided at the lower part of the biomass adsorption tower and for discharging the lower biomass in the adsorption tower.
[0028]
Moreover, an upper biomass discharge means for discharging the biomass in the upper part of the adsorption tower may be further provided at the upper part of the biomass adsorption tower.
[0029]
The biomass input means and the lower biomass discharge means may each have a function of intermittently driving and periodically discharging the biomass in the biomass adsorption tower periodically, You may have a function which discharges | emits the biomass in a biomass adsorption tower continuously quantitatively.
[0030]
As the lower biomass discharge means, more specifically, a cut-out screw feeder may be used, or a rake that can be rotationally driven may be used.
[0031]
On the other hand, as the upper biomass discharge means, it is necessary to uniformly discharge the upper layer of the biomass adsorbent that adsorbs a high concentration of trace components over time. .
[0032]
Further, the biomass adsorbent in the adsorption tower may be a moving bed using the above-described means, or a stirring blade may be combined as a uniform mixing means for the biomass layer in the adsorption tower. More specifically, a helical stirring blade can be used as the stirring blade.
[0033]
In addition, it is desirable that an adsorption biomass transfer means for transferring the adsorption biomass discharged from the biomass adsorption tower as a gasification biomass material to the biomass gasification furnace is further provided. With this configuration, even when a large amount of pulverized biomass is used as an adsorbent and the removal accuracy of trace components is improved, there is no problem with the treatment of biomass that has passed the adsorption limit. Offer again Salary By doing so, it can be concentrated and removed, so that useful components can be re-recovered among the removed components without polluting the environment.
[0034]
Further, in the gas purification line, it is desirable to further provide a dust removing device using a water jet jet upstream of the biomass adsorption tower. As a dust removing device using this water jet jet, a drive nozzle that sucks the generated gas and forms a water jet jet in the vertical axis direction, and a jet jet that is communicated with the drive nozzle and discharged from the drive nozzle. A scrubber unit that performs gas-liquid mixing of the water jet jet and the generated gas by receiving the cover so as to remove dust from the generated gas, a circulating water tank that stores the water jet jet water as circulating water, and the circulating water tank A suction inner cylinder provided with an opening having a weir around it, and a circulating water disposed in the suction inner cylinder, facing the opening of the scrubber outlet. A configuration including a discharge pipe forcibly discharging the gas by a circulation pump and a strainer interposed in the discharge pipe is suitable.
[0035]
As a more specific configuration of the dust removing device using the water jet jet, a configuration in which the liquid level of the suction inner cylinder is always kept lower than the circulating water tank is desirable. Therefore, a water level meter may be provided in the suction inner cylinder.
[0036]
The dust removal device using the water jet jet can sufficiently gas-liquid mix the generated gas and a large number of droplets, so that it can easily capture fine particle components of 0.3 μm or less, from the gas phase to the water phase. Can be separated. For similar reasons, NH _Three , HCN, Na, K, Cl and the like can be separated into an aqueous phase.
[0037]
Since the generated gas is cooled by the jet water, it is possible to condense and separate volatile components such as gaseous tar in the gas. By using jet jet water in a circulating manner, impurities trapped in the aqueous phase can be concentrated and separation becomes easy. This tar component can be recovered by the strainer for obtaining circulating water, and this tar component can be reused as a chemical raw material such as fuel and insecticide. In the water circulation line, it is necessary to provide means for appropriately replenishing the amount of water scattered from the outside of the system, particularly in the jet portion, in the circulation path.
[0038]
In the dust removing device using the water jet jet, since it acts to entrain the generated gas in the water jet jet injected into the cylindrical space, not only pressure loss does not occur, but conversely, pressure is applied to the subsequent gas flow. It is possible to contribute to the efficiency improvement of the entire gas purification line.
[0039]
In the biomass gasification system of the present invention, it is desirable to provide a conventional centrifugal separator for capturing fine particles of 1 μm or more in front of the dust removing apparatus using the water jet jet.
[0040]
Further, a conventional high-precision adsorption tower using activated carbon or ZnO as an adsorbent may be further provided downstream of the biomass adsorption tower as necessary.
[0041]
On the other hand, the biomass gasification method according to the present invention is a biomass gasification method using biomass as a fuel, as described above, and supplies biomass and a combustion oxidant to the biomass gasification furnace and at a predetermined temperature in the furnace. Is heated to produce a gas, and the produced gas is purified using at least biomass as an adsorbent.
[0042]
In such a configuration, gas adsorption may be performed while intermittently exchanging the biomass adsorbent quantitatively, or gas adsorption may be performed while the biomass adsorbent is continuously quantitatively exchanged. Further, the biomass adsorbent may be subjected to adsorption while stirring.
[0043]
Moreover, it is desirable to transfer the adsorbed biomass after use as the adsorbent to the biomass gasification furnace and use it as a gasified biomass material.
[0044]
Furthermore, it is desirable to perform dust removal of the generated gas using a water jet jet as a pre-process of the adsorption process using the biomass as an adsorbent. The generated gas dust removal using this water jet jet performs gas-liquid mixing of the generated gas and water in the cylindrical space by entraining the generated gas in the water jet jet flowing into the cylindrical space. The structure which isolate | separates the dust component and water-soluble component in water in water is preferable. The water used for the water jet jet is preferably recycled after filtration.
[0045]
This biomass gasification method is preferably implemented using the biomass gasification system described above, but may be implemented using other specific means as long as similar actions and effects can be obtained. it is obvious.
[0046]
【Example】
Hereinafter, the present invention will be described in more detail with reference to examples. The following examples are merely illustrative examples of the present invention, and do not limit the present invention.
[0047]
Example 1
FIG. 1 is an overall configuration diagram illustrating an example of a biomass gasification system according to the present invention. Elements common to those in FIG.
As shown in FIG. 1, the biomass gasification system according to the first embodiment includes a biomass supply unit 103 that supplies biomass 101 into a furnace body 102, and a combustion oxidant 104 that includes oxygen or a mixture of oxygen and water vapor. A biomass gasification furnace 106 provided with an oxidant supply means 105 for supplying gas into the furnace main body 102, and a separation means 108 such as a cyclone for removing dust in the product gas 107 gasified in the biomass gasification furnace 106. And a cooler 109 that cools the dust-removed gas, and a biomass adsorption purification device 1 that purifies the cooled gas by using the biomass 3 as an adsorbent.
[0048]
The biomass 3 used as the adsorbent may be the same as the biomass 101 supplied to the road main body 102, and is obtained by pulverizing and drying produced or discarded biomass. In the present invention, the biomass means a biological resource (for example, agricultural product or by-product, wood, plant, etc.) that can be used as an energy source or an industrial raw material. For example, sweet sorghum, napier grass, spirulina, etc. are used. ing.
[0049]
The separated solid content (ash) of 1 μm or more separated by the separation means 108 inevitably contains unburned and ungasified components. Therefore, in the biomass gasification system according to the present invention, it is arbitrarily obtained. There may be provided means 108 a for re-feeding the separated separated solids into the furnace body 102.
[0050]
The cooler 109 includes a type in which water is gas-liquid mixed with the gas 107 and a type in which water is indirectly contacted to exchange heat. When the former type of cooler is used, the carbon dioxide and oxygen separated inside the cooler are unnecessary as clean fuel gas, so they are recovered and, if necessary, recovered by the gas recovery means 109a. It may be transferred to the oxidant supply means and reused. In the latter case, since water vapor is generated by heat exchange, this water vapor may be similarly transferred to the oxidant supply means by the gas recovery means 109a and reused.
[0051]
The feature of the biomass gasification system shown in the present embodiment is that a biomass adsorption purification apparatus 1 using biomass as an adsorbent is provided on the downstream side of the cooler 109. In this embodiment, the gas purification line 2 includes at least the separation means 108, the cooler 109, and the biomass adsorption purification apparatus 1.
[0052]
The biomass adsorption and purification apparatus 1 is filled with biomass 3 and has a biomass adsorption tower 6 provided with an inlet 4 for the product gas and an outlet 5 for purified gas G that has passed through the biomass 3 inside. And a hopper (input means) 7 for supplying the biomass to the biomass adsorption tower 6 and a lower biomass discharge means 8 provided at the lower part of the biomass adsorption tower for discharging the lower biomass in the adsorption tower. As a component
[0053]
Further, the adsorbed biomass 3a discharged from the biomass adsorption tower 6 by the discharge means 8 is transferred to the biomass supply means 103 of the biomass gasification furnace 106 by the adsorption biomass transfer means 9 so as to be reused as a gasification biomass material. It has come to be. With this configuration, even when a large amount of pulverized biomass is used as an adsorbent and the removal accuracy of trace components is improved, there is no problem with the treatment of biomass that has passed the adsorption limit. Since it can be concentrated and removed by placing it, it is possible to re-collect useful components among the removed components without polluting the environment.
[0054]
(Example 2)
FIG. 2 shows a main part of a second embodiment of the biomass gasification system according to the present invention. The feature of the second embodiment is the detailed configuration of the biomass adsorption and purification apparatus 1. The biomass adsorption / purification apparatus 1 according to the second embodiment has a gas introduction port 41 and a gas discharge port 51 provided in a biomass adsorption tower 61 filled with biomass 3 as a basic configuration, and a hopper that supplies biomass to the biomass adsorption tower 61. 7 is the same as the biomass adsorption and purification apparatus 1 shown in Example 1, except that the lower biomass discharge means includes a cutting screw feeder 81 driven by a motor 81a. There is a feature in the point.
[0055]
The biomass adsorption tower 61 is a so-called moving bed type adsorption tower in which an internal biomass layer sequentially moves to the lower part by discharging biomass by a lower cutting screw feeder 81. The biomass 3 is filled into the upper portion from the hopper 7 through the rotary valve 7a by the amount discharged by the screw feeder 81 through the rotary valve 81a. Since this discharge and filling are usually performed when the amount of adsorption of the biomass 3 in the tower approaches the limit, it is intermittently and intermittently performed at predetermined time intervals. Of course, the screw feeder 81 can be continuously driven at a low speed to continuously discharge a small amount of biomass, and the feeding by the hopper 7 can be set continuously in proportion to the discharging speed.
[0056]
The adsorbed biomass 3a discharged by the screw feeder 81 through the rotary valve 81a mainly adsorbs tar components together with various trace components in the introduced gas, and the tar components are supplied to the oxidizing agent supplying means for each discharged biomass. By being transferred to 103, it is again used for gasification in the furnace body 102.
[0057]
(Example 3)
FIG. 3 shows a main part of a third embodiment of the biomass gasification system according to the present invention. The feature of the third embodiment resides in another detailed configuration of the biomass adsorption purification apparatus 1. In the biomass adsorption / purification apparatus 1 according to the third embodiment, as a basic configuration, the biomass adsorption tower 62 filled with the biomass 3 is provided with the introduction port 42 of the gas 107 and the discharge port 52 of the purified gas G. Although the point which has the hopper 7 which supplies biomass is the same as that of the biomass adsorption | suction refinement | purification apparatus 1 shown in the said Example 1 or 2, the point which has the lake 82 which can be rotated by the motor 82a as the lower biomass discharge | emission means. It is different and has this feature.
[0058]
The biomass adsorption tower 62 is a so-called moving bed type adsorption tower in which an internal biomass layer sequentially moves downward by discharging the adsorbed biomass 3a through the rotary valve 82a by the lower rake 82. By the amount discharged by the rotary rake 82, the hopper 7 fills the upper part with biomass through the rotary valve 7a. Since this discharge and filling are usually performed when the amount of biomass adsorbed in the tower approaches the limit, it is intermittently and intermittently performed every predetermined time. Of course, it is possible to continuously drive the rake 82 at a low speed to continuously discharge a small amount of biomass, and to set the charging by the hopper 7 in proportion to the discharging speed.
[0059]
The adsorbed biomass 3a discharged by the rake 82 mainly adsorbs tar components together with various trace components in the introduced gas, and the tar components are transferred to the oxidant supply means 103 for each discharged biomass. The gas is again used for gasification in the furnace body 102.
[0060]
Example 4
FIG. 4 shows a main part of a fourth embodiment of the biomass gasification system according to the present invention. The feature of the fourth embodiment is still another detailed configuration of the biomass adsorption purification apparatus 1. The biomass adsorption / purification apparatus 1 according to the fourth embodiment has, as a basic configuration, a biomass adsorption tower 63 filled with biomass 3 provided with an inlet 43 for gas 107 and an outlet 53 for purified gas G. The point which has the hopper 7 which supplies biomass is the same as that of the biomass adsorption | suction refinement | purification apparatus 1 shown in the said Example 1,2,3, Moreover, the rake | rotate 82 which can be rotated by the motor 82a is used as the lower biomass discharge | emission means. The point of having is the same as that of the said Example 3, However, the point by which the lake 83 is further provided in the upper part in a tower as an upper biomass discharge | emission means, and this point is characterized.
[0061]
The biomass adsorption tower 63 is a so-called moving bed type adsorption tower in which the internal biomass layer sequentially moves to the lower part by discharging the adsorbed biomass 3a through the rotary valve 82b by the lower rake 82. 3 is the same as the adsorption tower 62 in FIG. However, in the fourth embodiment, the rake 83 is also provided on the upper part, and the sorbed 83 can selectively remove the adsorbed biomass 3a in the upper part of the tower through the rotary valve 83b. Since the gas introduced into the tower first comes into contact with the upper biomass layer in the tower, the upper biomass layer reaches the adsorption limit earlier in the tower than the biomass layer below the intermediate layer. Therefore, if biomass is discharged from the bottom of the tower and the biomass layer is sequentially moved downward, and the biomass layer with a large amount of adsorption at the top is selectively removed, the biomass in the tower is always fresh biomass with high adsorption capacity. Will be maintained. In the configuration of FIG. 4, the lower rake 82 and the upper rake 83 are shown to be rotationally driven by the same motor 82 a, but can be driven separately using a switching gear or separately. You may comprise so that it can drive separately with this motor. By doing so, the upper rake 83 is driven first, the upper biomass layer approaching the adsorption limit is discharged preferentially, and then the lower biomass layer is discharged by the lower rake 82 so that the entire biomass layer is lowered. It can be moved, thereby maintaining the freshness of the biomass layer efficiently. The discharge by rake may be performed intermittently or may be performed so that a small amount is discharged continuously.
[0062]
In Example 4, the supply and discharge of biomass in the adsorption tower 63 can be performed by the following control system.
That is, the adsorption tower 63 is provided with a differential pressure detector 63a for detecting the differential pressure ΔP between the inlet portion and the discharge portion of the internal biomass layer. In addition, a level sensor 63b that detects the height of the biomass layer using ultrasonic waves or the like is provided, for example, at the top of the adsorption tower 63. Then, the rotary valves 83b and 82b are driven in order so that the layer differential pressure ΔP is in a certain range, and the biomass adsorbed with the tar component is discharged. As the biomass layer is discharged, the height level of the biomass layer decreases. Based on the detection value of the level sensor 63b, the rotary valve 7a is driven so that the level is maintained constant, and the biomass 3 is removed from the hopper 7 by the adsorption tower. Replenish in 63.
[0063]
(Example 5)
FIG. 5 shows a main part of a fifth embodiment of the biomass gasification system according to the present invention. The characteristic of the present Example 5 exists in the further detailed structure of the said biomass adsorption purification apparatus 1. FIG. The biomass adsorption / purification apparatus 1 according to the fifth embodiment has, as a basic configuration, a biomass adsorption tower 64 filled with biomass 3 provided with an inlet 44 for a gas 107 and an outlet 54 for a purified gas G. And having the hopper 7 for supplying biomass to the biomass adsorption tower 64 is the same as the biomass adsorption purification apparatus 1 shown in the first embodiment, but the biomass agitation for agitating the biomass in the tower in the tower As a means, the point which has the helical stirring blade 10 driven by the motor 10a differs, and this point has the characteristic.
[0064]
In the biomass adsorption tower 64, the internal biomass layer flows up and down by stirring the biomass in the tower by the helical stirring blade 10. The freshness of the biomass in the tower is maintained by the rotary valve 8a of the lower biomass discharge means 8 and the rotary valve 7a of the hopper 7, and the adsorption characteristics of the biomass layer in the tower are uniformly maintained by the helical stirring blade 10. As a result, the efficient utilization of the adsorption power of the biomass charged into the tower can be improved. If the above-mentioned moving bed type adsorption tower does not discharge and supply biomass relatively frequently, the amount of adsorbed tar components to the upper part of the biomass layer in the tower increases, and the adsorbed tar components become sticky to each other. Bed flow becomes difficult. On the other hand, in Example 5, the biomass layer in the tower can always be placed in a fluid state by the stirring means, so that it is not necessary to frequently discharge and supply biomass. That is, according to the fifth embodiment, “the upper part of the biomass layer becomes sticky by the tar component, which is likely to occur in the third and fourth embodiments shown in FIGS. 3 and 4, and the movement and flow of the biomass layer are inhibited. It is possible to prevent the “situation”.
[0065]
(Example 6)
FIG. 6 is an overall system diagram showing a sixth embodiment of the biomass gasification system according to the present invention. The feature of the sixth embodiment resides in that a dust removing device 11 using a water jet jet is further provided on the upstream side of the biomass adsorption and purification device 1 described above.
[0066]
As shown in FIG. 7, the dust removing device 11 using the water jet jet communicates with the drive nozzle 13 and the drive nozzle 13 that sucks the generated gas 107 to form the water jet jet 12 in the vertical axis direction. A cylindrical scrubber portion 14 for gas-liquid mixing the water jet jet 12 and the product gas 107 by receiving the water jet jet 12 discharged from the drive nozzle 13 so as to cover it, and for removing dust from the product gas 107; A circulating water tank 15 having a discharge port 15a for storing the water jet jet water as circulating water and sending out the generated gas from which the fine particle component and the water-soluble component are separated in the scrubber unit 14 to the biomass adsorption purification apparatus 1; , Disposed in the circulating water tank 15, opposed to the opening 14 g at the outlet of the scrubber portion 14, and around the weir 16 A suction inner cylinder 18 having an opening 17, a discharge pipe 20 that is disposed in the suction inner cylinder 18 and forcibly discharges circulating water in the suction inner cylinder 18 by a circulation pump 19, and the discharge pipe 20. And a strainer 21 interposed therebetween.
[0067]
The scrubber portion 14 is an integrally structured tubular member, and has a chamber portion 14a having a relatively large diameter, followed by a funnel-shaped suction portion 14b, a reduced diameter straight tubular throat portion 14c, and a diffuser that gradually increases in diameter. It is comprised from the part 14d and the exit pipe | tube part 14e of the wide straight pipe. The drive nozzle 13 is disposed in the center of the chamber portion 14 a, and the jet nozzle of the drive nozzle 13 is located at the center line of the scrubber portion 14. The gas inlet 14 f is formed in a side portion of the chamber portion 14 a and is set so as to entrain the generated gas in the water jet jet 12. In a state where the water jet jet 12 and the generated gas are mixed, the jet is placed in a compressed state by the suction portion 14b in the throat portion 14c having a reduced diameter straight tube and sufficiently gas-liquid mixing is performed. Thereafter, the jet is guided to the diffuser portion 14d that gradually expands in diameter and is diffused relatively rapidly, so that a gas-liquid separation phenomenon occurs and the gaseous tar component contained in the product gas 107 is condensed. The water stream that has absorbed the fine particle component and the water-soluble component formed by the water flows down from the widened straight tubular outlet pipe part 14e toward the suction inner cylinder 18, and the gas washed with water is the upper part of the circulating water tank 15. The gas is discharged from the gas discharge port 15a toward the biomass adsorption / purification apparatus 1 via the space.
[0068]
The opening 17 of the suction inner cylinder 18 is enlarged in diameter with respect to the lower main body portion of the suction inner cylinder 18, and the inner diameter of the enlarged opening 17 is the cylindrical shape located above the opening. The inner diameter of the lower opening 14g of the scrubber portion 14 is set somewhat larger. An orifice hole 18 a is formed in the lower side wall of the suction inner cylinder 18. Therefore, when the circulating pump 19 is driven to forcibly suck the circulating water in the suction inner cylinder 18 from the discharge pipe 20, the circulating water in the suction inner cylinder 18 is suddenly discharged, but the orifice hole 18a exists. Therefore, since the water is poured from there, the inside of the suction inner cylinder 18 does not become empty. However, since the amount of water injected from the orifice hole 18a is significantly lower than the discharge amount from the discharge pipe 20, the liquid level 18b in the suction inner cylinder 18 is the liquid level around the suction inner cylinder 18, that is, The state is always kept lower than the liquid level 15b in the circulating water tank 15. Thus, in order to maintain the liquid level 18b in the suction inner cylinder 18 lower than the surrounding liquid level 15b, it is mainly necessary to appropriately control the flow rate of the water jet jet 12 and the discharge amount by the circulation pump 19. Therefore, a water level meter (not shown) is provided in the circulating water tank 15 and the suction inner cylinder 18 so that the respective water level data can be measured in real time.
[0069]
The liquid surface position in the suction inner cylinder 18 may be higher than the opening face so as not to suck air from the opening face of the discharge pipe 20 and should be lower than the upper opening face of the suction inner cylinder 18. That's fine. Preferably, the liquid level in the suction inner cylinder 18 is set to have a large drop within a possible range from the opening surface.
[0070]
A plurality of V-shaped cutout grooves 17a are formed at the upper end of the upper enlarged opening portion 17 of the suction inner cylinder 18, and the plurality of grooves 17a allow the opening surface of the enlarged diameter opening portion 17 to The plurality of weirs 16 are formed. The plurality of weirs 16 may be referred to as triangular weirs 16 because of their shapes. When the liquid level in the circulating water tank 15 rises to the upper end of the triangular weir 16, the water flows down into the suction inner cylinder 18 through the V-shaped cutout groove 17a. The closer to the upper surface of the groove from the narrow lower part, the higher the flow rate. Therefore, water surface floating dust such as tar components that have been separated from the product gas 107 by the water jet jet 12 and cooled to become fine particles and then efficiently flow into the suction inner cylinder 18.
[0071]
Note that most of the falling water including the floating dust from the scrubber portion 14 directly flows into the suction inner cylinder 18 having the opening 17 having a diameter larger than that of the lower opening surface of the scrubber portion 14. Since the flowing energy of water is large, a part of it is scattered and scattered, and flows down into the circulating water tank 15 around the suction inner cylinder 18. The floating dust contained in the scattered flowing water is efficiently collected inside the suction inner cylinder 18 by the triangular weir 16 as described above. The floating dust collected in the suction inner cylinder 18 in this manner is knocked down below the water surface in the suction inner cylinder 18 by the falling jet water. If the circulating water in the suction inner cylinder 18 is not forcibly sucked by the circulation pump 19 before the floating dust struck deeply below the surface of the water rises again, the floating dust will remain in the suction inner cylinder 18 indefinitely. Therefore, it is necessary to adjust the amount of suction by the circulation pump 19 to a value at which the circulating water discharge speed exceeds the dust floating speed. This value can be adjusted by the circulation flow rate and the inner diameter of the main body of the suction inner cylinder 18.
[0072]
As described above, the circulating water in the suction inner cylinder 18 containing the floating dust efficiently recovered as described above is passed through the discharge pipe 20 by the circulation pump 19 to the strainer 21 at a speed exceeding the dust floating speed. The floating dust in the circulating water is removed and collected here, and the circulating water is cooled by the heat exchanger 22 and sent to the drive nozzle 13. A bypass pipe 23 is connected to the downstream side of the strainer 22, and the other end of the bypass pipe 23 is connected to the circulating water tank 15 so as to open into the circulating water tank 15. The amount of replenishing water into the circulating water tank 15 by the bypass pipe 23, the amount of scattered water flowing from the scrubber portion 14 into the circulating water tank 15, and the amount of water injected into the suction inner cylinder 18 from the orifice hole 18a. Thus, the water surface in the circulating water tank 15 can always be adjusted to a position where water flows from the triangular weir 16 into the suction inner cylinder 18. Flow meters 24a and 23a and flow rate adjusting valves 24b and 23b are attached to the circulation line 24 from the strainer 22 to the drive nozzle 13 and the bypass pipe 23, respectively. Is possible.
[0073]
The dust removal device using the water jet jet can sufficiently gas-liquid mix the generated gas and a large number of droplets, so that it can easily capture fine particle components of 0.3 μm or less, from the gas phase to the water phase. Can be separated. For similar reasons, NH _Three , HCN, Na, K, Cl and the like can be separated into an aqueous phase.
[0074]
Since the generated gas is cooled by the jet water, it is possible to condense and separate volatile components such as gaseous tar in the gas. By using jet jet water in a circulating manner, impurities trapped in the aqueous phase can be concentrated and separation becomes easy. This tar component can be recovered by the strainer 22 for obtaining circulating water, and this tar component can be reused as a chemical raw material such as fuel and insecticide. In the water circulation line, it is necessary to provide means for appropriately replenishing the amount of water scattered from the outside of the system, particularly in the jet portion, in the circulation path.
[0075]
In the dust removing device 11 using the water jet jet, since it acts to entrain the generated gas in the water jet jet injected into the scrubber portion 14 which is a cylindrical space, not only pressure loss does not occur, but conversely, The pressure applied to the subsequent gas flow is somewhat increased, which can contribute to the efficiency of the entire gas purification line.
[0076]
If necessary, a conventional high-precision adsorption tower using activated carbon or ZnO as an adsorbent may be further provided downstream of the biomass adsorption purification apparatus 1.
[0077]
【The invention's effect】
As described above, the biomass gasification system according to the present invention includes a biomass gasification furnace that gasifies the supplied biomass and a gas purification line that purifies the gas generated in the biomass gasification furnace. A biomass gasification system is characterized in that a biomass adsorption / purification apparatus using biomass as an adsorbent is provided in the gas purification line. Moreover, the biomass gasification method according to the present invention is a biomass gasification method using biomass as a fuel by supplying biomass and a combustion oxidant to a biomass gasification furnace and heating the inside of the furnace to a predetermined temperature. The gas is produced, and the produced gas is purified using at least a biomass adsorption purification process using biomass as an adsorbent.
[0078]
In the present invention, in the latter stage of the product gas purification line, although it does not reach the adsorption performance of activated carbon, it has practically effective adsorption characteristics and is inexpensive and can be used in large quantities as an adsorbent. Is the main feature. By passing a large amount of pulverized biomass through the gas purified by the conventional dust removal and tar component separation device in the previous stage, fine dust, particulate tar, hydrogen sulfide that could not be reduced to the detection limit conventionally Further, trace components such as chlorine and formaldehyde can be reduced to a desired content of a detection limit amount. Moreover, since this biomass adsorbent can be sequentially replaced under normal pressure, the adsorption adsorbent approaches the adsorption limit, and the discharged biomass adsorbent can be transferred to a gasifier and effectively used as a gasified biomass material. This high-accuracy adsorption removal process can be operated at a very low cost. In addition, since the biomass adsorbent is porous and lightweight, the pressure loss generated when the gas is allowed to pass through the adsorption is very small.
[0079]
As described above, according to the present invention, high-precision purification of product gas can be realized at low cost by a simple purification line configuration, reducing the pressure loss of the purification line, and requiring no backwashing of the purification element. A gasification system and a biomass gasification method can be provided.
[Brief description of the drawings]
FIG. 1 shows a first embodiment of a biomass gasification system according to the present invention, and is an overall configuration diagram of the biomass gasification system.
FIG. 2 shows a second embodiment of the biomass gasification system according to the present invention, and is a schematic configuration diagram of a biomass adsorption purification apparatus constituting the biomass gasification system.
FIG. 3 shows a third embodiment of the biomass gasification system according to the present invention, and is a schematic configuration diagram of a biomass adsorption and purification apparatus constituting the biomass gasification system.
FIG. 4 shows a fourth embodiment of the biomass gasification system according to the present invention, and is a schematic configuration diagram of a biomass adsorption and purification apparatus constituting the biomass gasification system.
FIG. 5 shows a fifth embodiment of the biomass gasification system according to the present invention, and is a schematic configuration diagram of a biomass adsorption purification apparatus constituting the biomass gasification system.
FIG. 6 shows a sixth embodiment of the biomass gasification system according to the present invention, and is an overall configuration diagram of the biomass gasification system.
FIG. 7 is a schematic configuration diagram of a dust removing device using a water jet jet constituting the biomass gasification system of the sixth embodiment.
FIG. 8 is an overall configuration diagram of a “system for gasifying biomass and producing methanol using the generated gas”, which is an example of a conventional biomass gasification system.
[Explanation of symbols]
1 Biomass adsorption purification equipment
2 Gas purification line
3 Biomass
4, 41, 42, 43, 44 Product gas inlet
5, 51, 52, 53, 54 Gas outlet
6, 61, 62, 63, 64 Biomass adsorption tower
7 Hoppers (biomass input means)
8 Lower biomass discharge means
9 Adsorption biomass transfer means
10 Helical stirring blade (biomass stirring means)
11 Dust remover using water jet
12 Water jet jet
13 Drive nozzle
14 Scrubber club
15 Circulating water tank
16 Weir
17 Opening of suction inner cylinder
19 Circulation pump
20 Discharge pipe for forcibly discharging circulating water in the suction cylinder
21 Strainer
81 Cutting screw feeder (lower biomass discharge means)
82 Rotatable rake (lower biomass discharge means)
83 Rotatable rake (upper biomass discharge means)
106 Biomass gasifier

Claims (8)

A biomass gasification system comprising a biomass gasification furnace for gasifying supplied biomass and a gas purification line for purifying gas generated in the biomass gasification furnace,
A biomass adsorption purification apparatus using biomass as an adsorbent is provided in the gas purification line ,
The biomass adsorption purification apparatus includes a biomass adsorption tower in which biomass is filled and an introduction port for the produced gas and an exhaust port for gas that has passed through the biomass in the interior. A biomass gasification system comprising: charging means for charging the gas; and lower biomass discharge means that is provided at a lower portion of the biomass adsorption tower and discharges biomass in the lower portion of the adsorption tower . The biomass gasification system according to claim 1 , further comprising upper biomass discharge means for discharging biomass in an upper part of the adsorption tower at an upper part of the biomass adsorption tower. The biomass gasification system according to claim 1 or 2 , further comprising biomass stirring means for stirring the biomass in the adsorption tower. The adsorption biomass transfer means which transfers the adsorption biomass discharged | emitted from the said biomass adsorption tower as a gasification biomass material to the said biomass gasification furnace is further provided, The any one of Claim 1 to 3 characterized by the above-mentioned. The biomass gasification system described. The biomass gasification system according to any one of claims 1 to 4 , further comprising a dust removing device that uses a water jet jet upstream of the biomass adsorption tower in the gas purification line. A dust removing device using the water jet jet,
A drive nozzle for sucking the generated gas and forming a water jet jet in the vertical axis direction;
A scrubber unit that communicates with the drive nozzle and gas-liquid mixes the water jet jet and the product gas by receiving the jet jet discharged from the drive nozzle so as to cover the product, and removes dust from the product gas;
A circulating water tank for storing the water jet jet water as circulating water;
A suction inner cylinder disposed in the circulating water tank, facing the opening of the scrubber outlet and having an opening having a weir around it;
A discharge pipe disposed in the suction inner cylinder and forcibly discharging the circulating water in the suction inner cylinder by a circulation pump;
The biomass gasification system according to claim 5 , further comprising a strainer interposed in the discharge pipe. The biomass gasification system according to claim 6 , wherein the liquid level of the suction inner cylinder is always kept lower than the circulating water tank. A biomass gasification method using biomass as fuel,
By supplying biomass and combustion oxidant to the biomass gasification furnace and heating the inside of the furnace to a predetermined temperature, gas is generated,
The product gas is purified using at least biomass as an adsorbent ,
The adsorbed biomass after use as the adsorbent is transferred to the biomass gasification furnace and used as a gasified biomass material,
The biomass gasification method characterized by performing dust removal of the generated gas using a water jet jet as a pre-process of the adsorption process using the biomass adsorbent .

Images