JPH033762Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Field of Application) This invention relates to a gas generator, and more specifically, to a gas generator that uses a fuel in the form of small pieces such as chips and sawdust as a raw material.

(Prior Art) Sawdust, which is generated in large quantities at sawmills, has conventionally been discarded without being used.

(Problem that the invention aims to solve) Therefore, the inventor thermally decomposed sawdust in a gas generating furnace to obtain a flammable gas whose main combustible components are carbon monoxide and hydrogen, and used this gas to drive a private generator. In order to realize the idea of using it as a fuel gas for internal combustion engines, we conducted various studies and found that since sawdust has a low specific gravity and poor fluidity, we poured a large amount of sawdust from above into a large cylindrical gas generating furnace. Even if it is attempted to cause thermal decomposition by continuously supplying gas, there is a problem that, for example, the degree of thermal decomposition tends to differ between near the center and near the outer periphery of the gas generating furnace, and the amount of combustible components in the gas produced varies widely. I found out that.

This invention is intended to solve the above-mentioned problems, and is intended to provide a gas generator that can obtain a large amount of combustible gas with a small amount of fluctuation in the amount of combustible components.

(Means for solving the problem) However, the gas generator of this invention consists of a plurality of cylindrical furnace shells with a furnace lid attached to the top and a rostrum at the bottom, erected on a foundation, and A fuel supply device equipped with an input pipe communicating with the inside of the furnace shell is disposed above the furnace shell, a gas outlet is provided at the top of the furnace shell, and an air supply port is provided below the rostrum of the furnace shell. The gas generating device is characterized in that the gas outlet of each of the furnace shells is connected to a collecting pipe leading to the gas use side.

(Function) In the gas generator of this invention, flaky fuel such as sawdust and chips is supplied into multiple furnace shells by the fuel supply device, and the flaky fuel is thermally decomposed in each furnace shell. The generated gases flow out from the gas outlet and are supplied to the user side through a collecting pipe in a merged state. Therefore, fluctuations in the amount of combustible components in the produced gas for each furnace shell are equalized by the merging of the produced gases, and the fluctuations in the amount of combustible components in the produced gas in the gas generator as a whole become small. In addition, the amount of gas generated in each furnace shell is a fraction of that of the entire equipment, so the furnace shell can be relatively small, and there is little variation in temperature within the cross section of the furnace shell, and the amount of gas generated in each furnace shell is small. Thermal decomposition is carried out in a stable state with little fluctuation in the amount of combustible components.

(Example) An example of this invention will be described below with reference to the drawings.

In the figure, reference numeral 1 denotes a cylindrical furnace shell, which is made of laminated refractory bricks, and has a tapered cylindrical surface whose inner circumferential wall 1a expands in diameter downward. The furnace shell 1 is the second
Four units are erected on a foundation 2, arranged at equal intervals on a circumference centered on point P in the figure, and have a common outer shell 5 consisting of a concrete outer wall 3 and a sand filling layer 4. surrounded by. 6 is a furnace lid attached to the top of the furnace shell 1, 7 is a rostol provided at the bottom of the furnace shell,
Reference numeral 8 designates an air supply port that opens below the rooster, and 9 designates a valve for adjusting the amount of air supplied to this air supply port. In addition, the lower part of the furnace shell 1 is provided with an ash outlet, an ignition port for fuel ignition, etc., but these are not shown. 10 is a fuel supply system, which is installed on floor 1 of the building fixed to foundation 2.
A short cylindrical fuel storage tank 12 is arranged on top of the shaft 15, and a shaft 15 is connected to a support 13 fixed to the building through a bearing 14.
is attached rotatably around a vertical axis, and the upper end of the charging cylinder 16 that penetrates each furnace lid 6 is attached to the fuel storage tank 12.
The support arm 17 is opened on the bottom surface 12a of the shaft 15.
The winding wing 18 fixed via the winding blade 18 is turned along the bottom surface 12a (separated by a small distance). As shown in FIG. 4, the rear edge of the rotating blade 18 is inclined upward with respect to the traveling direction indicated by the arrow X, and the opening 16a at the upper end of each charging cylinder 16
It is arranged so that it passes over the top. 19 is axis 1
5 is a chain-driven reducer, 20 is a reducer 19
Both are attached to the support column 13. Further, 21 is a conveyor for carrying in sawdust. In addition, in the furnace lid 6 penetration part of the charging cylinder 16,
A cylindrical container-shaped water trough 22 fixed to the furnace lid 6 and a seal ring 23 fixed to the charging tube 16
A water seal device 24 is provided. On the other hand, 25 is a primary dust removal device that removes and cools the generated gas from the gas generating furnace 26 configured as described above using a water shower. The upper outlet 29 is connected to a collecting pipe 30 that reaches the gas usage side via a secondary dust removal device, a dehumidification device, etc. (none of which are shown). In the primary dust removal device 25, small pieces of wood are filled as a filter material 31 in the water shower falling portion, but other types of devices may be used.
32 is a water supply pipe, and 33 is a drain pipe.

In order to thermally decompose sawdust to obtain flammable gas in the gas generator 34 having the above configuration, the conveyor 2
1, the sawdust 35 is supplied into the fuel storage tank 12, the rotation blade 18 is rotated, the sawdust 35 is filled into each furnace shell 1 through the charging tube 16, and the lowest part of this sawdust layer is ignited. If air (mixed with water vapor if necessary) is circulated upward in each furnace shell 1 by gas suction on the user side or suction from the air supply port 8, etc., the sawdust 35 in each furnace shell 1 will be A combustion (oxidation) layer L _a , a reduction layer L _b , and a carbonization (preheating) layer L _c are formed from below, and a generated gas containing carbon monoxide and hydrogen as main combustible components is obtained from the gas outlet 27 . This generated gas is transferred to the primary dust removal device 25.
After merging inside and removing dust, a single collecting pipe 3
The air is supplied to the user's internal combustion engine (engine) through the subsequent secondary dust removal device and dehumidification device, and is used as a power source for driving a generator. As the sawdust in the furnace shell 1 is heated, its volume decreases and it falls to the lower part by its own weight. However, the sawdust 35 in the fuel storage tank 12 is constantly moved to the charging tube 16 by the continuously rotating rotating blades 18 of the fuel supply device 10. Since the sawdust is supplied into the furnace shell 1 through the charging tube 16, each furnace shell 1 is maintained filled with sawdust, and stable thermal decomposition is performed.

Although the amount of gas produced in each furnace shell 1 and the component ratio of the gas vary slightly over time, all furnace shells 1
Since the generated gases are combined and supplied to the user side through the collecting pipe 30, the fluctuations in the amount of gas produced and the component ratio of the gas generator 34 as a whole flowing out of the collecting pipe 30 are equalized and reduced. Since each furnace shell 1 needs to be relatively small, there is little variation in temperature within the cross section of the furnace shell, and a large amount of generated gas with a substantially constant flow rate and constant components can be obtained. . According to the inventor's experiments, using the gas generator 34 with the above configuration (however, the average inner diameter of the furnace shell 1 is 1200 mm, and the height of the furnace shell 1 is 4000 mm), sawdust with a water content of 35% is continuously supplied, and the amount of air supplied ( When thermal decomposition is performed by changing the amount of gas generated (equivalent to the amount of gas generated) in three stages, a combustible gas containing 17 to 18% CO (volume %, same hereinafter) and 25 to 28% _H2 as combustible components is stably obtained. I was able to do that. On the other hand, the average inner diameter is 2000
In a comparative experiment in which sawdust was continuously supplied and thermally decomposed using one large furnace shell with a height of 4,000 mm and a height of 4,000 mm, CO in the combustible gas was 17.5 to 24.0%.
_H2 was 9.0 to 12.3%, and both results showed a wide range of variation.

This invention is not limited to the above embodiment; for example, in the above embodiment, the inner wall surface 1a of the furnace shell 1
Since it has a tapered cylindrical surface shape whose diameter expands downward, the sawdust in the furnace shell 1 smoothly descends due to its own weight, and is caused by friction with the inner wall surface 1a. Inner wall surface 1a
This method has the advantage of preventing the occurrence of the breathing phenomenon in which cavities are created in the sawdust close to the sawdust and the composition of the produced gas fluctuates due to the collapse of these cavities. Good too. In addition, in the above embodiment, since each furnace shell 1 is surrounded by a common outer shell, the construction work of the outer shell can be carried out in a short period of time, and the installation space for the gas generating furnace can be reduced. It can also be surrounded by an outer shell. Further, as the fuel supply device, a device having a configuration other than the above, such as a device in which a vibrator is attached to a hopper-shaped fuel storage tank, can be used. Further, in the above embodiment, the gas outlet 27 was connected to the collecting pipe 30 via the primary dust removal device 25, but by directly connecting the gas outlet 27 to the collecting pipe 30, the generated gas from each furnace shell 1 is first collected. After merging in the pipe 30, dust removal etc. may be performed.

Although the above description has been given of a gas generator using sawdust as fuel, this invention can also be applied to a gas generator using coarse chips or the like as fuel rather than sawdust.

(Effects of the invention) As explained above, according to this invention, the produced gases generated in multiple furnace shells connected to the fuel supply system are combined and supplied to the user side through the collecting pipe. The gas generator as a whole can continuously obtain a large amount of combustible gas with little variation in the amount of combustible components, and is a resource-saving device that can effectively use sawdust and chips as combustible gas for in-house power generation, etc. A useful gas generator is provided.

[Brief explanation of the drawing]

Fig. 1 is a longitudinal sectional view of a gas generator showing an embodiment of this invention, Fig. 2 is a sectional view taken along the line A-A in Fig. 1, and Fig. 3 is a plan view taken along the line B-B in Fig. 1. FIG. 4 is a sectional view taken along line CC in FIG. 3. 1... Furnace shell, 1a... Inner wall surface, 2... Foundation, 3
...Outer wall, 6... Hearth, 7... Rostle, 8...
Air supply port, 10... Fuel supply device, 12... Fuel storage tank, 15... Shaft, 16... Input tube, 16a... Opening, 18... Rotating blade, 20... Motor, 27...
...Gas outlet, 30...Collecting pipe, 34...Gas generator.

Claims (1)

[Scope of Claim for Utility Model Registration] 1. A plurality of cylindrical furnace shells with a furnace lid attached to the top and a rostrum at the bottom are erected on a foundation, and a charging cylinder is provided that communicates with the inside of the furnace shell. A fuel supply device is disposed above the furnace shell, a gas outlet is provided at the top of the furnace shell, an air supply port is provided below the rostrum of the furnace shell, and a gas outlet is provided at each of the furnace shells. A gas generator characterized in that the gas generator is connected to a collecting pipe leading to a gas usage side. 2. The gas generator according to claim 1, wherein each furnace shell is surrounded by a common outer shell. 3. The gas generator according to claim 1 or 2, wherein the inner wall surface of the furnace shell has a tapered cylindrical shape whose diameter increases downward. 4. Utility model registration claim 1 or 2 or 4, wherein the fuel supply device is provided with a rotating blade that passes over the opening of the charging cylinder in a fuel storage tank in which the charging cylinder opens at the bottom. The gas generator according to item 3.