JP2004339327A - Carbonization apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a carbonization apparatus for producing charcoal, bamboo charcoal, and the like, with which carbonization is carried out in an extremely high thermal efficiency in a short time, a manufacturing cost of charcoal is reduced, apparatus constitution is simple and an installation cost is reduced. <P>SOLUTION: This carbonization apparatus is equipped with a furnace body 10 having a plurality of air inlets 13a at its inside bottom part, a lid plate 4 for opening and closing a material doorway 1a at the top of the furnace body 10, a heating flue 2 which is stood in the furnace body 10 and has its top reaching the vicinity of the ceiling part of the furnace body 10 and a carbonization furnace 1 having an air intake port 17a and a flow rate control valve 56. In the carbonization apparatus, an ignition part is laid at the bottom side and a carbonizing material T charged in the furnace body 10 is spontaneously burnt in a state of oxygen deficiency and carbonized. The heating flue 2 has double column structure of an outer column 22 having a lower part equipped with an exhaust inlet 24 communicating with an in-furnace space 10a and a closed upper part and an inner column 2 having an upper end opening in the vicinity of the top in the outer cylinder 22 and a lower end communicating with an exhaust route 3 to the outside of the furnace. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a carbonization device for spontaneously burning and carbonizing a vegetable material such as a piece of wood or bamboo in an oxygen-deficient state.
[0002]
[Prior art]
In recent years, charcoal and other types of charcoal have attracted attention for their excellent properties such as humidity control, deodorization, negative ion release, harmful substance adsorption, fungicidal and anti-mite properties. In addition to placing it under the floor, placing it in a rice cooker, immersing it in drinking water or bath water, etc., it also uses shredded or powdered building materials such as wall materials, ceiling materials, flooring materials, sliding doors and so on. Products in the form of sandwiches such as partitions and tatami mats, and those stored inside beddings such as futons have also been commercialized, and are further used for soil modification, mixed with resins and ceramic materials, etc. Applications are expanding in various fields, and the demand is increasing.
[0003]
However, charcoal produced by a classic charcoal kiln is dense and hard, as typified by Bincho charcoal, and is not suitable for applications such as deodorants, adsorbents, or soil modifiers. It takes a lot of time and effort, is poor in mass productivity, has a low profitability, is limited in terms of raw materials, is expensive, and has a great limitation on the location of the pot.
[0004]
Therefore, the inventor of the present invention first provided, as a carbonization device, a heating tube for carbonization having a hot air introduction hole at the bottom inside a furnace body having an opening at the upper end with an access port with an open / close lid. From the vicinity of the upper end opening, a cross-section tube extending from the vicinity of the upper end opening and extending across the furnace body passes through the side wall of the furnace body and is piped to the outside as an exhaust cylinder, and at the bottom of the furnace body, It has been proposed to provide an air inlet (Patent Document 1).
[0005]
According to this carbonization device, the carbonization material loaded in the furnace body is ignited from the bottom side and spontaneously combusts in a state of oxygen shortage. The carbonization material is heated by the hot air rising from below and the hot air radiated from the red-hot carbonization heating cylinder to the surroundings, thermally decomposes, further reaches the self-combustion temperature, and spontaneously burns.・ The increase in combustion gas accompanying the expansion of the pyrolysis region produces a synergistic effect of raising the temperature of the heating tube for carbonization and increasing the heat radiation, thereby accelerating the progress of the pyrolysis reaction and expanding the spontaneous combustion region, and loading The whole amount of the carbonized material thus carbonized will be carbonized in a short time.
[0006]
In addition, such a carbonizing device can use various raw materials as a carbonizing material, and is excellent in deodorizing performance and adsorptive performance, and can mass-produce soft quenched carbon which is easy to pulverize in a short period of time. Since it has many advantages that it is simple and is not restricted by the installation place, it has already been put to practical use and has been well received.
[0007]
[Patent Document]
JP-A-2003-119468
[0008]
[Problems to be solved by the invention]
However, even in the above-mentioned carbonization apparatus, there is still room for improvement in terms of thermal efficiency and operability, and it is necessary to efficiently carbonize in a shorter time in order to reduce coal production cost and improve workability. Is required. For example, in the carbonization device, an exhaust passage from the heating tube for carbonization to the outside is not directly led out above the furnace main body, but is connected to an external exhaust passage through a transverse tube, so that a high-temperature combustion gas is removed. Although the heat loss is suppressed by lengthening the discharge path in the furnace main body to promote red heating by the heat storage of the heating cylinder, the amount of heat taken out of the furnace from the exhaust path is still large, and the furnace temperature It takes a long time for carbonization due to the delay in ascent, and when loading the carbonizing material into the furnace body and taking out the obtained carbide, the transverse cylinder arranged radially near the inlet / outlet obstructs work. There was a difficulty that it was difficult.
[0009]
In view of the above situation, the present invention provides a simple and effective improvement to the carbonization device according to the above proposal, thereby further shortening the carbonization time by a very high thermal efficiency and thereby further reducing the coal production cost. An object of the present invention is to make it possible to improve the workability of loading the carbonizing material and taking out the obtained carbide, and to reduce the equipment cost by simplifying the apparatus configuration.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, a carbonization apparatus according to claim 1 of the present invention is provided with a substantially closed furnace body 10 having a plurality of air introduction holes 13a at an inner bottom, as shown by reference numerals in the drawings. A cover plate 4 for opening and closing the material inlet / outlet 1 a provided at an upper portion of the furnace body 10, a heating / exhaust tube 2 erected inside the furnace body 10 and having an upper end reaching near the ceiling of the furnace body 10, The carbonization furnace 1 includes an air inlet 17a for supplying air to the air inlets 13a, and an air supply amount adjusting means (flow rate adjusting valve 56) for the air inlet 17a. A double cylinder consisting of an outer cylinder 22 having a lower portion provided with exhaust introduction holes 24 communicating with the furnace space 10a and having an upper portion closed, and an inner cylinder 23 arranged concentrically in the outer cylinder 22 is formed. The upper end of the inner cylinder 23 opens near the top in the outer cylinder 22. At the same time, the lower end communicates with the exhaust path 3 to the outside of the furnace, and the bottom side of the furnace main body 10 is used as an ignition portion (elbow tube 16) to convert the carbonizing materials T loaded in the furnace main body 10 into oxygen. It is configured so that it is spontaneously burned in a shortage state and carbonized.
[0011]
The invention according to claim 2 is the carbonization device according to claim 1, wherein an inner bottom plate 13 provided with the plurality of air introduction holes 13 a at the bottom of the furnace main body 10 and an outer bottom plate disposed below the inner bottom plate 13. The ignition chamber 15 includes an air intake 17a and an ignition heat source inlet 15a. According to a third aspect of the present invention, in the carbonization apparatus according to the second aspect, a bottom plate receiving portion 11c is provided on a bottom side peripheral surface in the furnace main body 10, and the inner bottom plate 13 is provided on the bottom plate receiving portion 11c with an outer peripheral portion. Are mounted in a non-fixed state.
[0012]
According to a fourth aspect of the present invention, there is provided the carbonization apparatus according to any one of the first to third aspects, further including a gas reburning furnace 5 for reburning the combustion exhaust gas discharged from the carbonization furnace 1. According to a fifth aspect of the present invention, in the carbonization apparatus according to the fourth aspect, outside air supplied to the air intake 17a of the carbonization furnace 1 is exchanged with high-temperature exhaust gas discharged from the gas reburning furnace 5 by heat exchange. A heat exchange unit (heat exchange jacket 53) for increasing the temperature is provided.
[0013]
The invention according to claim 6 is the carbonization device according to any one of claims 1 to 5, wherein the peripheral wall portion 11 of the furnace main body 10 forms a double wall, and the inorganic fibers are formed between the inner and outer walls (inner and outer metal plates 11a and 11b). And a heat insulating material 9b made of inorganic fibers is stretched on the inner peripheral surface of the furnace body 10 via a metal holding net 12.
[0014]
The invention according to claim 7 is the carbonization apparatus according to any one of claims 1 to 6, wherein the entire upper surface side of the furnace main body 10 constitutes the material inlet / outlet 1a. The heating / exhaust tube 2 forming a heavy cylinder is provided upright, and a donut-shaped metal storage basket 80 having a tubular section (inner cylindrical portion 80b) at the center for inserting the heating / exhaust tube 2 from below is provided. , And the carbonizing materials T are loaded into the furnace main body 10 in a state of being stored in the storage basket 80.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, one embodiment of a carbonization device according to the present invention will be specifically described with reference to the drawings. FIG. 1 is a plan view of the entire carbonizing apparatus including accessory equipment, FIG. 2 is a side view, FIG. 3 is a front view, and FIG. 4 is a rear view. 1 to 4, reference numeral 1 denotes a carbonization furnace, 5 denotes a gas reburning furnace, 6 denotes a wood vinegar extractor, 7 denotes a cooling tower, and C denotes a control box, which are installed on a rectangular base frame 8. I have.
[0016]
As shown in detail in FIGS. 5 to 8, the carbonization furnace 1 has a furnace main body 10 formed in a vertical cylindrical shape with a bottom and having an upper end opening as a material entrance 1 a, and a central portion in the furnace main body 10. The heating exhaust pipe 2 is provided upright, an exhaust pipe 3 connected to the heating exhaust pipe 2 and extending from the bottom of the furnace main body 10, and a cover plate 4 for closing the material port 1 a of the furnace main body 10. ing.
[0017]
The furnace body 10 has a double wall structure in which a peripheral wall portion 11 is provided with a heat insulating material 9a made of glass wool between inner and outer metal plates 11a and 11b, and a heat insulating material made of rock wool is formed on the inner peripheral surface of the peripheral wall portion 11. 9b is stretched through a metal holding net 12, and an ignition chamber 15 is formed at the bottom between an inner bottom plate 13 and an outer bottom plate 14, both of which are made of metal, and a lower surface of a rightward portion of the outer bottom plate 14 is formed. An elbow pipe 16 having one end fixed to the side and extending to the right outside is provided. The elbow pipe 16 forms an ignition heat source introduction port 15a communicating with the ignition chamber 15, and is shorter than the side outside along the front-rear direction. An air supply pipe 17 penetrates through the peripheral wall portion 11 and protrudes into the ignition chamber 15, and an inner end opening thereof forms an air supply port 17a. The ignition heat source inlet 15a can be opened and closed by a cover plate 18 which is attached to and detached from the outer end flange portion 16a of the elbow pipe 16 via screw fasteners 18a, 18a.
[0018]
The inner bottom plate 13 of the furnace main body 10 has a donut plate shape, and has a large number of air introduction holes 13a formed on the entire surface thereof. Are fixed by welding, and the outer peripheral portion is provided on the inner periphery of the furnace main body 10 in a state where the inner peripheral portion is screwed to the upper flange 19a of the short metal cylinder 19 disposed at the center of the furnace main body 10. It is placed in a non-fixed state on bottom plate receiving portions 11c. The outer bottom plate 14 of the furnace main body 10 has a donut plate shape like the inner bottom plate 13, but is welded and fixed to the peripheral wall portion 11 at the outer peripheral portion. The short cylindrical body 19 is fixed to the outer bottom plate 14 via bolts and nuts 21a at the lower flange 19b thereof, integrally with the metal annular receiving plate 20 disposed on the lower surface side of the outer bottom plate 14. I have.
[0019]
The heating exhaust cylinder 2 has a metal outer cylinder 22 having a height such that the upper end closed by the end plate 22a reaches the vicinity of the material port 1a of the furnace main body 10, and is disposed concentrically within the outer cylinder 22 and has an upper end. Form a double cylinder composed of a metal inner cylinder 23 opening near the closed upper end of the outer cylinder 22, and a large number of exhaust introduction holes 24 are formed around the lower part of the outer cylinder 22 facing the furnace space 10a. Is established. Thus, the outer cylinder 22 was screwed in from the outside, with the lower part inserted through the inside of the short cylindrical body 19 and the lower end placed on the annular receiving plate 20 in the upper part, equally spaced in the circumferential direction. By setting the tips of the plurality of screw-shaped pins 25 to abut against the inner cylinder 23, it is set so as to maintain the concentric state with respect to the inner cylinder 23. On the other hand, the inner tube 23 is connected to the flange 23a provided at the lower end thereof together with the connection flange 30 of the exhaust pipe 3 on the lower surface side of the annular receiving plate 20 via mounting bolts 21b. Are integrally fixed to the furnace main body 10 in a state of communicating with the furnace main body 10. The annular space 2a between the outer cylinder 22 and the inner cylinder 23 is closed from the outside of the furnace by the connection between the flange portion 23a of the inner cylinder 23 and the annular receiving plate 20.
[0020]
The exhaust pipe 3 includes a horizontal pipe portion 3a extending rearward from the center below the furnace main body 10, and a vertical pipe portion 3b extending upward from the rear end of the horizontal pipe portion 3a in proximity to the outer peripheral surface of the furnace main body 10. The flexible connection pipe 31 to be connected to the exhaust treatment path is detachably connected to the rear side of the upper end of the vertical pipe section 3b via a clamp band 31a. . Further, a temperature sensor S1 for measuring the temperature of the combustion exhaust gas passing through the inside of the vertical pipe portion 3b is provided. A cheese pipe 32 is used at the front end of the horizontal pipe 3a, the connection between the horizontal pipe 3a and the vertical pipe 3b, and the upper end of the vertical pipe 3b. By closing the branch opening 32a of the non-connecting portion with the cap 33, the cap 33 is removed during furnace shutdown so that the inside of the pipe can be easily cleaned.
[0021]
Thus, trapezoidal support frames 26a, 26b are erected on both left and right sides of the furnace body 10, and the bearing bodies 27a, 27b provided at the upper ends of the support frames 26a, 26b are slightly closer to the lower part of the furnace body 10. By pivotally supporting the pivots 28, 28 protruding on the left and right sides of the position, the furnace main body 10 is placed on both support frames 26a, 26b in the upright posture shown by the solid line in FIG. It is supported to be convertible to. Reference numeral 29 denotes a posture changing handle that protrudes from the gear box 34 on the bearing 27b side. The rotation of the handle causes the furnace body 10 to communicate with the exhaust pipe 3 via a worm reduction gear mechanism (not shown) in the gear box 34. It turns up and down together.
[0022]
The cover plate 4 is formed separately from the furnace main body 10 into a circular thick plate having a heat insulating material 9a made of glass wool interposed between metal front and back plates 41a and 41b. A pair of right and left columns 42a and 42b are provided upright at the rear of the furnace body 10, and a pair of right and left inverted V-shaped mounting arms 44 and 44 are provided on a pivot 43 provided between upper portions of both columns 42a and 42b. A fixing plate 44 is fixed at an intermediate portion, the cover plate 4 is attached to the front ends of the mounting arms 44, 44, and a prismatic balance weight 45 is fixed to the rear ends of the mounting arms 44, 44. A gear box 45 forming a bearing of the pivot 43 is provided at the upper end of the right column 42b, and the worm reduction in the gear box 45 is performed by rotating a cover opening / closing handle 46 protruding from the gear box 45. The pivot 43 rotates integrally with the two mounting arms 44, 44 via a gear mechanism (not shown), whereby the cover plate 4 is switched between the closed position shown by the solid line in FIG. 5 and the open position shown by the imaginary line in FIG. It is configured as follows.
[0023]
A plurality of tightening screw-type clamps 35 are pivotally attached to the periphery of the material entrance 1a of the furnace main body 10 at regular intervals so as to be able to be turned upside down and rotatable. A grooved projection 47 corresponding to each clamp 35 is provided in a projecting manner. With the cover plate 4 covering the material entrance 1a, the shaft of each clamp 35 is engaged with the groove of the grooved projection 47. The cover plate 4 is set in such a manner that the cover plate 4 is pressed against the material port 1a to be in a sealed state by being inserted and turning the screw portion to tighten. In FIGS. 2, 3, 5, and 6, only two sets of the clamp 35 and the grooved projection 47 are shown to avoid complicating the drawings.
[0024]
As shown in FIGS. 1 and 2, an upper pipe connection port 36a for directly sending combustion exhaust gas from the carbonization furnace 1 to the gas reburning furnace 5 is provided at an upper portion of the wood vinegar liquid extractor 6, and the combustion exhaust gas. And a lower pipe connection port 36b for sending the gas to the gas reburning furnace 5 through the wood vinegar liquid extractor 6, and the outlet of the exhaust pipe 3 of the carbonization furnace 1 is connected to the flexible connection pipe 31. , One of the two pipe connection ports 36a and 36b can be selected and connected. When the flue gas from the carbonization furnace 1 flows into either of the two pipe connection ports 36a and 36b, the combustion exhaust gas flows through the air supply fan 37 provided at the top of the wood vinegar liquid extractor 6 in FIGS. The gas is supplied to the lower part in the gas reburning furnace 5 through an air supply pipe 38 shown in FIG. At the top end of the air supply pipe 38, a temporary exhaust port 39 with a manual opening / closing valve 39a is provided.
[0025]
The gas reburning furnace 5 completely decomposes trace organic substances and the like contained in the combustion exhaust gas from the carbonization furnace 1 by setting the inside to a high-temperature combustion state by the ignition of the attached kerosene burner 50, and thus the exhaust gas is removed. It functions to make it harmless and odorless, and the temperature inside the furnace is measured by a thermometer 51. As shown in FIG. 4, outside the exhaust pipe 52 extending from the upper part of the gas reburning furnace 5, a heat exchange having a ventilation path 53 a helically circulating around the exhaust pipe 52 is provided inside. A jacket 53 is provided. An air inlet 54 a that opens to the outside is provided below the heat exchange jacket 53, and an air outlet 54 b in the upper part is connected to an air supply pipe 55 to the carbonization furnace 1. Therefore, during the operation of the carbonization furnace 1, the air supplied to the ignition chamber 15 of the carbonization furnace 1 is taken in from the air inlet 54 a of the heat exchange jacket 53, and is exhausted while passing through the ventilation path 53 a of the heat exchange jacket 53. It exchanges heat with the high-temperature exhaust gas passing through the cylinder 52 and flows into the ignition chamber 15 from the air supply port 17a through the air supply pipe 55 in a state where the temperature is raised.
[0026]
The air supply pipe 55 includes a vertical pipe 55a descending from the heat exchange jacket 53 side and a horizontal pipe 55b extending forward from the lower end thereof along the base frame 8, and a front end of the horizontal pipe 55b. A flow control valve 56 is interposed on the side. A flexible connection pipe 57 is connected to a front end of the horizontal pipe 55b, and a free end of the flexible connection pipe 57 is connected to the outside of the air supply pipe 17 of the carbonization furnace 1 through a clamp band 57a. A temperature sensor S2 for measuring the temperature of the air passing through the air supply pipe 55 is provided in front of the flow control valve 56, as shown in FIG. At the same time, a pipe 55c having a distal end forming an auxiliary air supply port 58 with a manual opening / closing valve 58a is connected to the upstream side of the temperature sensor S2.
[0027]
The flow control valve 56 controls the temperature of the combustion exhaust gas measured by the temperature sensor S1 of the exhaust pipe 3 based on control data previously input to a control device (not shown) in the control box C, The opening degree is automatically adjusted by a command signal from the control device in accordance with the temperature of the supply air measured, the elapsed time from the start of the processing, and the like, thereby increasing or decreasing the air supply amount into the carbonization furnace 1. It is set as follows.
[0028]
As shown in FIG. 9, the wood vinegar liquid extractor 6 has an outer water-cooled jacket 6a formed between a funnel-shaped inner casing 61 and a bottomed cylindrical outer casing 62 as shown in FIG. An inner water-cooling jacket 6b is formed between the inner tube 63a and the outer tube 63b of the double tube 63 arranged along the vertical direction of the center of the inside of the tube 61, and the outer tube 63b of the double tube 63 and the inner casing 61 The space between them is an extraction chamber 60 provided with a spiral fin 64. The extraction chamber 60 is provided with a liquid outlet port 60a with an open / close valve which communicates with the lower pipe connection port 36b at the upper part and which projects downward through the outer casing 61 at the center of the bottom. The lower end of the inner cylinder 63a is open to the vicinity of the bottom. Thus, the inner tube 63a of the double tube 63 protrudes upward and outward as an exhaust tube, and is connected to the air supply tube 38 to the gas reburning furnace 5 through the air supply fan 37, as shown in FIG. Although omitted, the upper pipe connection port 36b (see FIG. 2) communicates with the outwardly projecting portion.
[0029]
The upper end of the outer water-cooled jacket 6a and the upper end of the inner water-cooled jacket 6b are connected by a communication pipe 65, and the drain pipe 66 is connected to the upper end of the inner water-cooled jacket 6b. A water supply pipe 67 with an on-off valve 67a is connected to the lower end. The drain pipe 66 and the water supply pipe 67 are connected to the cooling tower 7, and the cooling water is circulated and cooled by passing the cooling water through the cooling jackets 6a and 6b by the operation of the pump 7a (see FIG. 1) of the cooling tower 7. It has become. In FIG. 9, reference numeral 81 denotes a frame on which the wood vinegar liquid extractor 6 is installed, 82 denotes a container for collecting the wood and bamboo vinegar liquid drawn out from the liquid outlet 60 a, and 83 denotes a container on which the container 83 is carried. It is a trolley for
[0030]
In order to produce carbide by the carbonization apparatus having the above configuration, first, the cover plate 4 of the carbonization furnace 1 is opened, and a carbonization material T such as wood or bamboo chips is introduced from the material entrance 1a, as shown in FIG. To the furnace space 10a of the furnace body 10 as described above. Thereafter, the cover plate 4 is closed, and is fixed to the furnace main body 10 with clamp fittings 35..., And an ignition heat source such as a flame of the gas burner G is introduced into the open ignition heat source inlet 15 as shown in FIG. I do. As a result, the combustion gas of the ignition heat source and the heated air fill the ignition chamber 15 in a mixed state, and further enter the furnace space 10a through the air introduction holes 13a of the inner bottom plate 13 and thereby carbonize the lowermost portion. The material for use T is ignited, and thermal decomposition by spontaneous combustion is started. Thus, the ignition heat source inlet 15a is closed by the cover plate 18 when the lowermost carbonizing material T starts spontaneous combustion.
[0031]
With the start of the spontaneous combustion, the generated high-temperature combustion gas rises through the gap between the carbonizing materials T and propagates the hot air from below to above, and a part of the combustion gas is exhausted from the exhaust inlet 24. .. Are drawn into the annular space 2a between the outer cylinder 22 and the inner cylinder 23 of the heating / exhaust cylinder 2 and ascend the annular space 2a and flow into the inner cylinder 23 at the top of the heating / exhaust cylinder 2; It descends inside the inner cylinder 23 and flows out to the exhaust pipe 3. Then, the lower part of the outer cylinder 22 of the exhaust pipe 2 is heated from both the inner and outer sides by the hot air of the combustion gas passing through the heated exhaust pipe 2 and the hot air generated by the spontaneous combustion of the surrounding carbonizing materials T. I do. Further, as the spontaneous combustion in the furnace interior space 10a expands, the reddish portion of the outer cylinder 22 gradually expands upward due to the increased hot air and heat storage of the combustion gas, and the inner cylinder 23 also begins to glow red. The entire heating exhaust pipe 2 becomes red hot.
[0032]
As a result, the carbonizing materials T in the furnace space 10a are heated by the hot air rising from below and the hot air radiated from the heated exhaust pipe 2 to the surroundings, and the lower side and the center of the deposited layer are heated. Pyrolysis starts from both sides, reaches the self-combustion temperature, and burns spontaneously. As the area of the spontaneous combustion / pyrolysis expands, the heated exhaust pipe 2 further increases the temperature of both the outer cylinder 22 and the inner cylinder 23 due to the increase of the inflowing combustion gas, thereby increasing the heat radiation to the surroundings. As a result, the progress of the thermal decomposition reaction of the carbonizing material T and the expansion of the spontaneous combustion region are accelerated, and the entire furnace interior space 10a eventually becomes a uniform high temperature state, and all of the loaded carbonizing material T is thermally decomposed and carbonized. I do.
[0033]
In the carbonization process, air is sucked from the air supply port 17 a into the ignition chamber 15 with the discharge of the combustion exhaust gas from the heating exhaust pipe 2. By limiting with the valve 56, the furnace space 10a is maintained in an oxygen-deficient state. Accordingly, the carbonizing material T continues to thermally decompose in a state where the carbon component hardly burns due to incomplete combustion, and eventually carbonizes completely inside.
[0034]
Further, since the furnace temperature of the carbonizing furnace 1 changes depending on the increase or decrease of the amount of air supplied into the ignition chamber 15 from the air supply port 17a, it can be adjusted by opening and closing the flow control valve 56 and changing the opening degree. The opening and closing of the flow control valve 56 and the adjustment of the opening degree are performed by obtaining processing temperature conditions according to the type and size of the carbonizing material T to be used, the water content, the charged amount, and the like based on test data obtained in advance. This is input to a control device (not shown) in the control box C as control data associated with the temperature measured by the temperature sensors S1 and S2 and the furnace temperature, and is input by a command signal from the control device. What is necessary is just to set it to perform automatically.
[0035]
When general wood chips or bamboo chips are used as the carbonizing material T, the furnace temperature may be set so as to normally be maintained at about 350 ° C. to 500 ° C., but spontaneous combustion is particularly activated in the initial stage. For this purpose, for example, conditions may be set such that the temperature temporarily reaches nearly 1000 ° C. within one hour from the start of processing. In addition, the temperature of the combustion exhaust gas measured by the temperature sensor S1 is a value that is generally several hundred degrees Celsius lower than the furnace temperature. Thus, if the treatment temperature conditions can be set arbitrarily as described above, carbides of the same quality can always be produced as long as the types of carbonizing materials T are the same. However, it is also possible to produce carbides having different properties by using different pyrolysis temperatures even if they are the same.
[0036]
When the thermal decomposition of the carbonizing material T ends, the temperature of the combustion exhaust gas rapidly decreases. Therefore, the completion of the carbonization can be determined by detecting the temperature by the temperature sensor S1. After the completion of the carbonization, the flexible connection pipes 31 and 57 connected to the exhaust pipe 3 and the air supply pipe 17 are detached after the temperature of the generated carbide is lowered to some extent, and the clamp tool 35 is removed to remove the handle 46. 5, the lid 4 is opened as shown by the imaginary line in FIG. 5, an appropriate container or sheet is arranged in front of the furnace main body 10, and the handle 29 is operated to move the furnace main body 10 into the same phantom line. As shown in the figure, the body is tilted forward until it is slightly lower than the horizontal, and the generated charcoal such as charcoal or bamboo charcoal flows out, and if necessary, it can be scraped off with an appropriate tool.
[0037]
In the carbonization furnace 1, high-temperature flue gas generated by the spontaneous combustion of the carbonizing material enters the outer cylinder 22 from the lower part of the heating exhaust cylinder 2 having a double cylinder structure, rises from the inner top end, and rises. It flows into the inner cylinder 23, descends, and flows out of the furnace from the bottom of the furnace body 1. That is, the exhaust path of the combustion exhaust gas in the furnace main body 10 is about twice as long as a configuration in which the heating exhaust cylinder is connected to an exhaust pipe above the furnace main body as a single cylinder structure. Further, the length of the heating exhaust cylinder (heating cylinder for carbonization) is significantly longer than that of the prior art described above, in which the heating exhaust cylinder (carbonization heating cylinder) is connected to an external exhaust pipe via a radially traversing cylinder from the top. Therefore, in this carbonization treatment, the amount of heat transmitted from the combustion exhaust gas to the heating exhaust pipe 2 increases due to the long exhaust path, the amount of heat taken out of the furnace by the exhaust gas decreases accordingly, high thermal efficiency can be obtained, and the path can be improved. Is reciprocated up and down in the double cylinder, so that red heat is rapidly generated by the heat storage of the entire heating and exhausting cylinder 2, and the temperature in the furnace rises quickly due to heat radiation from the heating and exhausting cylinder 2, thus causing carbonization. The progress of thermal decomposition and spontaneous combustion of the materials T is promoted, the time required for complete carbonization is reduced, and a high carbonization efficiency can be achieved.
[0038]
Further, as in the present embodiment, the entire upper surface side of the furnace main body 10 constitutes the material inlet / outlet 1a, and the single heating / exhaust cylinder 2 forming the double cylinder is disposed at the center of the furnace main body 10. For example, after the entire heating exhaust tube 2 is red-heated, the entire furnace space 10a is in an evenly heated state by uniform heat radiation from the central portion, so that a uniform high-quality carbide can be obtained. In addition, it is possible to load the carbonizing material T... Into the furnace main body 1 and take out the processed carbide by using a metal storage basket 90 having a donut shape in cross section as shown in FIG. .
[0039]
In the storage basket 90, an outer cylindrical portion 90a and an inner cylindrical portion 90b are connected and integrated at a bottom portion not shown in the drawing and are opened upward, and a metal frame 91 for holding the cage form is provided. An outer diameter of the outer cylindrical portion 90 a is slightly smaller than an inner diameter of the furnace body 10, and an inner diameter of the inner cylindrical portion 90 b is It is set slightly smaller than the outer diameter. According to the storage basket 90, as shown in the drawing, the carbonizing material T is stored in the donut-shaped storage space in the cross section between the outer and inner cylinders 90a and 90b, and the crane is attached to the arc-shaped handle 93 attached to the upper edge. (Not shown) and the like. The heating and exhausting tube 2 is inserted into the inner cylindrical portion 90b from below with the hanging hook 94, and the storage basket 90 is loaded into the furnace main body 1, and the lid plate 4 (FIG. After the treatment, the storage basket 90 is lifted upward from the furnace main body 10 in the same manner as during loading without tilting the furnace main body 10 as described above. Since the whole amount of the carbide generated by the extraction and removal can be taken out at once, the workability is remarkably improved. Therefore, as the carbonization furnace 1 becomes larger, it becomes a great advantage that such a storage basket 90 can be used.
[0040]
In the configuration of the prior art carbonization apparatus having the transverse cylinder as in the carbonization furnace, the transverse cylinder also contributes to the thermal decomposition of the carbonizing material and the promotion of spontaneous combustion by heat radiation. In addition, it takes a long time, and the heat radiation is concentrated on the top part of the furnace space and a portion centered in one radial direction, so that the furnace space is not easily heated uniformly, and furthermore, the transverse tube becomes an obstacle. Therefore, such a storage basket cannot be used.
[0041]
On the other hand, the combustion exhaust gas discharged from the heating exhaust pipe 2 is sent to the gas reburning furnace 5 and recombusted as described above. Therefore, even if a trace amount of organic matter is included in the gas, it is completely decomposed. And the exhaust gas finally discharged to the outside becomes non-toxic and odorless. In this embodiment, the introduced outside air to be supplied to the carbonization furnace 1 is heated by heat exchange in the heat exchange jacket 53 using heat of the exhaust gas discharged from the gas reburning furnace 5. The thermal efficiency is further improved as compared with the case where cold outside air is directly taken in, the pyrolysis and spontaneous combustion of the carbonizing materials T in the furnace body 10 proceed more efficiently, and the entire carbonizing apparatus is utilized by utilizing the heat of the exhaust gas. Even so, waste of heat energy is reduced.
[0042]
By the way, as in the old years, as in the industrial practice of wood carbonization, the volatile components that evaporate as wood and bamboo are heated contain various useful organic components, mainly acetic acid. Wood vinegar is obtained from wood and bamboo vinegar is obtained from bamboo, and these are now valuable. Therefore, in the carbonization apparatus of this embodiment, the wood vinegar or bamboo vinegar is extracted by connecting the exhaust pipe 3 of the carbonization furnace 1 to the lower pipe connection port 36b passing through the wood vinegar liquid extractor 6. So that they can be collected.
[0043]
That is, the flue gas discharged from the carbonization furnace 1 is guided to the connection port 36b, and flows into the upper part of the extraction chamber 60 as shown by the solid line arrow in FIG. It flows down, flows into the inner cylinder 63a of the double pipe 63 from the bottom, rises, and is sent to the air supply pipe 38 to the gas reburning furnace 5 through the air supply fan 37, but spirals in the extraction chamber 60. During the cooling process, the temperature of the cooling water flowing through the inner and outer water-cooling jackets 6b and 6a is exchanged with the cooling water to lower the temperature, and the volatile component mainly composed of acetic acid is condensed with the cooling. Since this condensed component accumulates in the bottom of the extraction chamber 60 as a wood vinegar solution or a bamboo vinegar solution as shown by the dashed arrow in the figure, the condensed component flows out of the liquid outlet port 60a with an on-off valve and is collected in a container 82 disposed below. it can.
[0044]
In the carbonization apparatus of the above embodiment, an ignition chamber 15 is provided at the bottom of the furnace body 10 between the inner bottom plate 13 provided with a plurality of air introduction holes 13a. Since the ignition chamber 15 is provided with the air intake 17a and the ignition heat source inlet 15a, when the ignition heat source is introduced into the ignition heat source inlet 15a at the start of the carbonization process, the combustion gas is discharged to the entire ignition chamber 15. , The carbonized material T... Loaded in the furnace space 10a ignites uniformly over the entire lower surface, and air flowing in from the air intake 17a also flows from the entire ignition chamber 15 into the furnace space 10a. Thus, the pyrolysis and spontaneous combustion of the carbonizing materials T proceed uniformly and efficiently upward from the entire lower surface of the deposition layer.
[0045]
Further, in the carbonization device of this embodiment, the inner bottom plate 13 is placed in an unfixed state on the bottom plate receiving portion 11c provided on the bottom side peripheral surface in the furnace body 10 because the inner bottom plate 13 is not fixed. Does not deform itself nor distorts the peripheral wall portion 11 of the furnace body 10 even if the dimensional change due to the thermal expansion during the carbonization process and the shrinkage after the process is repeated. It is improved and has a long life. Further, since the outer cylinder 22 of the heated exhaust cylinder 2 is mounted on the annular receiving plate 20 in a non-fixed manner and is not fixed to the furnace main body 10, the exhaust introduction holes 24 are clogged due to accumulation of soot and the like. Or when the amount of adhered substances on the inner and outer peripheral surfaces of the outer cylinder 22 and the inner cylinder 23 increases, the outer cylinder 22 can be easily pulled out from the material entrance 1a side for cleaning, and the inner cylinder 23 exposed by this pulling out can be cleaned. Can also be easily cleaned.
[0046]
Further, in the carbonizing apparatus of this embodiment, a heat insulating material 9a made of glass wool is loaded between the inner and outer metal plates 11a and 11b of the peripheral wall portion 11 forming the double wall of the furnace body 10, and the furnace body 10 Since the heat insulating material 9b made of rock wool is stretched on the inner peripheral surface via the metal holding net 12, heat radiation to the outside through the peripheral wall portion 11 is suppressed, and the thermal efficiency of the carbonization process is improved accordingly. At the same time, it is possible to prevent the inner and outer metal plates 11a and 11b of the peripheral wall portion 11 from being heated to a high temperature, and in particular to prevent the heat deterioration due to the high temperature of the inner metal plate 11a, so that the furnace body 10 has increased durability and a longer life. There is.
[0047]
Examples of the carbonizing material T to be used include wood chips, bamboo chips, nut shells such as nut shells, and these can be used in a mixed form, and there is no problem even if the sizes are not uniform. In the case of wood chips and bamboo chips, waste wood and bamboo products have been conventionally discarded and incinerated, such as waste wood and bamboo scraps, unnecessary cuttings and remaining materials generated in the sawing and processing processes, shavings, pruned cuttings, and cut grass. What was the target can also be used.
[0048]
Although the carbonization apparatus of the embodiment includes the wood vinegar liquid extractor 6 and the cooling tower 7 as accessory equipment, the carbonization apparatus of the present invention may be configured without these accessory equipment, or may be a water heater or a dryer using exhaust gas heat. It is good also as a structure which has various other accessory facilities, such as. In addition, the carbonizing furnace 1 is of a pivotable type that can be tilted in the above-described embodiment. However, as the fixed type, the loading of the carbonizing materials T... In this fixed type, a structure in which the cover plate 4 is pivotally attached to the furnace main body 10 may be used. The heating exhaust tube 2 may have a structure in which a plurality of heating exhaust tubes 2 are erected in the furnace main body 10.
[0049]
Further, the means for adjusting the amount of air supplied to the air inlet 17a of the furnace main body 10 is not limited to the means for performing automatic adjustment using the flow control valve 56 or the like in the above-described embodiment, but may be one for performing manual adjustment using a manual valve or a damper. Good. Further, the heat insulating material 9a loaded inside the peripheral wall portion 11 forming the double wall in the furnace body 10 and the heat insulating material 9b stretched on the inner peripheral surface of the peripheral wall portion 11 are not limited to the glass wool and the rock wool described above. Other high-melting inorganic fibers can also be used. In addition, the design of the detailed configuration such as the form of each part, the mutual connection structure, the pipe configuration, the installation position of the air supply fan and the on-off valve, and the like in the carbonization apparatus of the present invention can be variously changed in addition to the embodiment.
[0050]
【The invention's effect】
According to the first aspect of the present invention, a substantially hermetic furnace body having a plurality of air introduction holes in an inner bottom portion, a cover plate for opening and closing a material inlet / outlet at an upper portion thereof, and a furnace standing upright in the furnace body and having an upper end provided therein. In a carbonization apparatus having a heating exhaust cylinder reaching the vicinity of a main body ceiling portion, and a carbonization furnace having an air intake for supplying air to the air introduction hole and an air supply amount adjusting means, the heating exhaust cylinder is concentrically arranged. The outer cylinder has a double cylinder structure consisting of an outer cylinder and an inner cylinder.The outer cylinder has an exhaust introduction hole communicating with the furnace space in the lower part, and the upper part is closed. Since it is configured to open in the vicinity and communicate the lower end to the exhaust path to the outside of the furnace, high-temperature flue gas generated by the spontaneous combustion of the carbonizing material goes up and down in the heated exhaust cylinder to exit the furnace. As a result, the amount of heat transmitted from the combustion exhaust gas to the heated exhaust stack increases, In addition to high thermal efficiency, red heat is rapidly generated by the heat storage of the entire heating stack, and the temperature inside the furnace rises quickly due to heat radiation from the heating stack, thereby causing thermal decomposition and spontaneous combustion of the carbonizing material. Accelerated, the time required for complete carbonization is shortened, and a high carbonization efficiency can be achieved.
[0051]
According to the second aspect of the present invention, in the carbonization apparatus, an ignition chamber formed between the inner bottom plate provided with the plurality of air introduction holes and the lower outer bottom plate is provided at the bottom of the furnace main body. Since the chamber is provided with the air intake and the ignition heat source introduction port, the combustion gas when the ignition heat source is introduced into the ignition heat source introduction port spreads over the entire ignition chamber, and the carbonization material charged in the furnace body. Is uniformly ignited from the entire lower surface, and the air flowing from the air intake is also uniformly supplied from the entire ignition chamber into the furnace space, so that the thermal decomposition and spontaneous combustion of the carbonizing material are performed on the lower surface of the sedimentary layer. Efficiently and efficiently proceeding upward from the whole, higher carbonization efficiency can be obtained.
[0052]
According to the invention of claim 3, in the carbonization device, the furnace has a bottom plate receiving portion on the bottom side peripheral surface in the furnace main body, and the inner bottom plate is placed on the bottom plate receiving portion such that the outer peripheral portion is not fixed. Therefore, even if the inner bottom plate repeatedly undergoes dimensional changes due to thermal expansion during the carbonization process and shrinkage after the process, the inner bottom plate does not deform itself or distort the peripheral wall portion of the furnace main body, so Furnaces have increased durability and longer life.
[0053]
According to the invention of claim 4, since the carbonization apparatus includes the gas reburning furnace for reburning the combustion exhaust gas discharged from the carbonization furnace, even if a small amount of organic matter is included in the gas, it is completely removed. The exhaust gas that is decomposed and ultimately discharged to the outside becomes non-toxic and odorless, and does not impose a burden on the environment.
[0054]
According to the fifth aspect of the present invention, in the carbonization apparatus having the above-described gas reburning furnace, the heat exchange unit for raising the temperature of the introduced outside air supplied to the carbonization furnace by heat exchange with the high-temperature exhaust gas discharged from the gas reburning furnace. Therefore, the thermal efficiency of the carbonization process is further improved, and the thermal decomposition and spontaneous combustion of the carbonizing material in the furnace main body progresses more efficiently, and the waste heat energy of the entire carbonizing device is reduced by utilizing the heat of the exhaust gas. Less.
[0055]
According to the invention of claim 6, in the carbonizing apparatus, the peripheral wall of the furnace main body forms a double wall, and a heat insulating material made of inorganic fibers is loaded between the inner and outer walls, and the inner peripheral surface of the furnace main body is provided. Since the heat insulating material made of inorganic fiber is stretched through the metal holding net, heat radiation to the outside through the peripheral wall portion is suppressed, and the thermal efficiency of the carbonization process is improved accordingly, and the peripheral wall portion is The heat deterioration of the metal plate caused by the high temperature is prevented, and the furnace body has an increased durability and a longer life.
[0056]
According to the invention of claim 7, in the carbonization apparatus, the entire upper surface side of the furnace main body constitutes the material inlet / outlet, and one heating / exhaust cylinder forming the double cylinder stands upright at the center of the furnace main body. On the other hand, a doughnut-shaped material storage basket having a tubular portion into which the heating exhaust cylinder is inserted in the center is provided, and the carbonizing material is loaded into the furnace main body while being stored in the material storage basket. Since the heating exhaust stack is configured to be red-hot, the entire furnace space is in an evenly heated state with uniform heat radiation from the center, thereby obtaining a uniform high-quality carbide. The loading of the carbonized material and the removal of the carbide after processing can be performed by the storage basket at the same time, and the mechanical force of a crane or the like can be used to move the storage basket into and out of the furnace body, thereby significantly improving the workability of the loading and unloading. Improved, especially carbonized But it is advantageous in the case of a large-sized.
[Brief description of the drawings]
FIG. 1 is a plan view of an entire carbonizing device according to an embodiment of the present invention.
FIG. 2 is a side view of the carbonizing device.
FIG. 3 is a front view of the carbonization device.
FIG. 4 is a rear view of the carbonizing device.
FIG. 5 is a side view of the carbonization furnace in the carbonization apparatus, taken along line AA of FIG. 3;
FIG. 6 is a vertical sectional side view of the carbonization furnace.
FIG. 7 is a cross-sectional plan view of the carbonization furnace taken along the line 6B-B of FIG.
FIG. 8 is a vertical sectional front view of a lower portion of the carbonization furnace.
FIG. 9 is a vertical side view of a wood vinegar liquid extractor in the carbonization device.
FIG. 10 is a perspective view showing a loading operation of a carbonizing material using a storage basket in the carbonizing apparatus.
[Explanation of symbols]
1 Carbonization furnace
1a Material entrance
2 Heated exhaust pipe
3 Exhaust pipe
4 lid plate
5 Gas reburning furnace
6 Wood vinegar liquid extractor
9a, 9b insulation
10 Furnace body
10a Furnace space
11 Perimeter wall
11a Inside metal plate (inner wall)
11b Outside metal plate (outer wall)
11c Bottom plate receiving part
12 holding net
13 Inner bottom plate
13a Air inlet
14 Outer bottom plate
15 Ignition room
15a Heat source inlet for ignition
16 Elbow tube (ignition part)
17a Air intake
22 outer cylinder
23 inner cylinder
24 air inlet
53 Heat exchange jacket (heat exchange section)
56 Flow control valve (Air supply amount control means)
80 metal storage basket
80b Inner cylindrical part (cylindrical part)
T Material for carbonization

Claims (7)

A substantially closed furnace main body having a plurality of air inlet holes at an inner bottom, a lid plate for opening and closing a material entrance provided at an upper portion of the furnace main body, and a furnace main body ceiling standing upright in the furnace main body and having an upper end. A heating exhaust cylinder that reaches the vicinity of the air inlet, an air intake that supplies air to the air introduction hole, and a carbonization furnace having an air supply amount adjustment unit for the air intake,
The heating exhaust cylinder has a double cylinder consisting of an outer cylinder closed at the top with an exhaust introduction hole communicating with the furnace space at the bottom, and an inner cylinder concentrically arranged in the outer cylinder,
The inner cylinder has an upper end that is open near the top in the outer cylinder, and a lower end that communicates with an exhaust path to the outside of the furnace,
A carbonization apparatus configured to use the bottom side of the furnace main body as an ignition portion to spontaneously burn and carbonize a carbonizing material loaded in the furnace main body in an oxygen-deficient state. At the bottom of the furnace body, there is provided an ignition chamber formed between an inner bottom plate provided with the plurality of air introduction holes and an outer bottom plate arranged below the inner bottom plate. The carbonization device according to claim 1, further comprising an ignition heat source inlet. 3. The carbonizing apparatus according to claim 2, further comprising a bottom plate receiving portion on a bottom side peripheral surface in the furnace main body, wherein the inner bottom plate is placed on the bottom plate receiving portion in a non-fixed outer peripheral portion. The carbonization apparatus according to any one of claims 1 to 3, further comprising a gas reburning furnace for reburning combustion exhaust gas discharged from the carbonization furnace. The carbonization apparatus according to claim 4, further comprising a heat exchange unit that raises the temperature of external air supplied to an air intake of the carbonization furnace by heat exchange with high-temperature exhaust gas discharged from the gas reburning furnace. The peripheral wall of the furnace body forms a double wall, and a heat insulating material made of inorganic fibers is loaded between the inner and outer walls thereof, and a heat insulating material made of inorganic fibers is provided on the inner peripheral surface of the furnace body via a metal holding net. The carbonizing device according to claim 1, wherein the carbonizing device is stretched. The entire upper surface side of the furnace main body constitutes the material inlet / outlet, and a single heating / exhausting cylinder forming the double cylinder is erected at the center of the furnace main body, while the heating / exhausting cylinder is inserted in the center. 7. A doughnut-shaped metal storage basket having a cross section, wherein the carbonization material is stored in the storage basket and loaded into the furnace body. The carbonizing device as described.

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