JP4074479B2 - Wood material dryer - Google Patents

Description

【００３６】
因みに、１次処理装置２００での処理により木質系素材４００の含水率が上述の範囲に到達したか否かは、通常、木質系素材の種類毎に、燻煙熱処理時における経過時間と含水率変化との関係を燻煙熱処理時の設定温度毎に調べておき、そのデータから経過時間に基づいて判断することができる。
【００３７】
次に、１次処理装置２００において燻煙熱処理された木質系素材４００を第１素材収容室２３０から取り出し、２次処理装置３００に移す。ここでは、第２素材収容室３１０の扉３１１を開放し、それにより形成される開口部から上側および下側の各棚板３１２上に第１素材収容室２３０から取り出した木質系素材４００を載せる。木質系素材４００を収容した後、第２素材収容室３１０は、扉３１１を閉鎖して密閉する。
【００３８】
一方、木質系素材４００が取り出された１次処理装置２００側においては、第１素材収容室２３０内に新たな木質系素材４００を収容する。そして、新たに収容された木質系素材４００に対し、上述の要領により、同様の燻煙熱処理を施す。
【００３９】
１次処理装置２００における新たな木質系素材４００の燻煙熱処理時において、第１素材収容室２３０から排出される高温の煙は、排煙路２４０の主排煙路２４２を移動中に温度が低下し、分岐路２４４、２４５，２４６を通じて第２素材収容室３１０内に流入する。そして、第２素材収容室３１０内に流入した煙は、煙突３１４から徐々に外部に排出される。これにより、第２素材収容室３１０内は、排煙路２４０からの煙による気流が通過することになる。この気流は、第２素材収容室３１０の片側から分岐路２４４、２４５，２４６を通じて流入し、第２素材収容室３１０の反対側に設けられた煙突３１４から排出されるので、第２素材収容室３１０内の全体に概ね均等に行き渡ることになる。また、この気流は、第２素材収容室３１０内を第１素材収容室２３０側の内部温度よりも低い温度に全体的に加熱する。この結果、第２素材収容室３１０内に配置された木質系素材４００は、第１素材収容室２３０内での温度環境よりも低温の温度環境下において、煙の気流により処理され、再び乾燥処理される（二次乾燥処理）。ここで、木質系素材４００は、第１素材収容室２３０内での燻煙熱処理時に生じた乾燥応力が調整されて均一化され、反りやねじれなどの歪がさらに抑制される。すなわち、木質系素材４００は、２次処理装置３００において、１次処理装置２００での場合に比べて穏やかな温度環境下でさらに乾燥処理されることにより、乾燥度合いがさらに高まり、同時に、反りやねじれがさらに抑制されて均質になる。換言すると、２次処理装置３００においては、反りやねじれなどの歪が少なく、しかも乾燥度合いが高められた木質系素材４００を得ることができる。
【００４０】
なお、第２素材収容室３１０内を通過する気流は、各分岐路２４４、２４５，２４６のダンパー２４７，２４８，２４９を調節して煙の流入量を制御することにより、第２素材収容室３１０内により均一に行き渡らせることができる。また、そのようなダンパー２４７，２４８，２４９の調節により、第２素材収容室３１０内の温度を全体的により均一化させることができる。したがって、第２素材収容室３１０内に収容された木質系素材４００は、配置位置に拘わらず、全体的に均質に乾燥処理され得る。
【００４１】
また、２次処理装置３００における木質系素材４００の二次乾燥処理では、１次処理装置２００からの排煙を利用して第２素材収容室３１０内に気流を生じさせると共に第２素材収容室３１０内を加熱しているので、木質系素材４００を経済的に二次乾燥処理することができる。
【００４２】
２次処理装置３００による木質系素材４００の処理は、第２素材収容室３１０内の温度、すなわち、木質系素材４００の二次乾燥処理時の温度を６０〜９０℃に設定して実施するのが好ましく、７０〜８０℃に設定して実施するのがより好ましい。この温度が６０℃未満の場合は、木質系素材４００の乾燥度合いが高まりにくくなり、また、一次乾燥処理時に木質系素材４００に生じた乾燥応力が均一化されにくくなる可能性がある。一方、９０℃を超える場合は、木質系素材４００が過乾燥状態になって新たな乾燥応力が発生し、それが製材時の狂いの原因になるおそれがある。
【００４３】
因みに、第２素材収容室３１０内の温度は、通常、第１素材収容室２３０からの煙の温度が主排煙路２４２を移動中に低下しているため、当該煙を第２素材収容室３１０内に導入すると、上述の範囲に設定され得る。
【００４４】
また、２次処理装置３００による木質系素材４００の処理は、通常、木質系素材４００の含水率（二次乾燥処理後含水率）が、燻煙熱処理前の木質系素材４００の含水率（上述の処理前含水率）の５〜１５％になるまで実施するのが好ましい。二次乾燥処理時の温度を上述の範囲に設定しながら木質系素材４００の二次乾燥処理後含水率をこのように設定した場合、木質系素材４００に生じた乾燥応力をより効果的に調整して均一化することができ、反りやねじれなどの歪がより効果的に抑制された木質系素材４００を得ることができる。
【００４５】
なお、二次乾燥処理後含水率は、次の式（３）により得られる。式（３）において、二次処理後重量は、第２素材収容室３１０において処理した後の木質系素材４００の重量を意味している。
【００４６】
【数２】

【００４７】
因みに、２次処理装置３００での処理により木質系素材４００の含水率が上述の範囲に到達したか否かは、通常、木質系素材の種類毎に、経過時間と含水率変化との関係を２次処理装置３００での設定温度毎に調べておき、そのデータから経過時間に基づいて判断することができる。
【００４８】
２次処理装置３００において二次乾燥処理された木質系素材４００は、燻煙熱処理のために表面に煤が付着しているので、必要に応じて表面を取り除いた後、適宜裁断して建材や家具用材として用いられる。
【００４９】
［他の実施の形態］
（１）上述の実施の形態では、第１素材収容室２３０内に棚板２３４を２段に配置し、木質系素材４００を上下方向に２段に重ねて収容できるように構成したが、棚板２３４を３段以上配置し、木質系素材４００を３段以上に重ねて収容できるように構成することもできる。また、棚板２３４は、必ずしも２段以上の多段に配置する必要はなく、木質系素材４００を横方向に並べて収容するように構成することもできる。
【００５１】
（２）上述の実施の形態では、燃焼室２１０内に配置された木質系燃料に着火バーナー２１１を用いて着火したが、木質系燃料は、燃焼室２１０内に火種を投入して着火することもできる。
【００５２】
【発明の効果】
本発明の木質系素材乾燥装置は、上述のような１次処理装置と、この１次処理装置から排出される煙を導入可能な２次処理装置とを備えているため、木質系燃料の燃焼により発生する煙で木質系素材を燻して乾燥させるに当り、木質系素材を効率的に乾燥させると共に、木質系素材に生じる歪を抑制することができる。したがって、この木質系素材乾燥装置を用いれば、反りやねじれなどの歪が少ない乾燥木質材料を得ることができる。
【図面の簡単な説明】
【図１】本発明の実施の一形態に係る木質系素材乾燥装置の概略平面図。
【図２】図１のＩＩ−ＩＩ断面図。
【図３】図１のＩＩＩ−ＩＩＩ断面図。
【図４】前記木質系素材乾燥装置に採用された１次処理装置の第１素材収容室の底部の平面図。
【符号の説明】
１００ 木質系素材乾燥装置
２００ １次処理装置
２１０ 燃焼室
２２０ 煙道
２２１ 底部
２３０ 第１素材収容室
２３２ 底部
２３３ 開口部
２４０ 排煙路
２４４ 第１分岐路
２４５ 第２分岐路
２４６ 第３分岐路
２５０ ダンパー
３００ ２次処理装置
３１０ 第２素材収容室
４００ 木質系素材[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wood-based material drying apparatus, and more particularly to an apparatus for dripping and drying a wood-based material with smoke generated by combustion of a wood-based fuel.
[0002]
[Prior art and its problems]
Wood-based materials such as logs obtained by cutting trees such as conifers and broad-leaved trees contain a large amount of moisture, so they can be used as building materials or furniture materials by cutting them into the required shapes as they are. It is difficult. For this reason, the wood-based material is usually used as a building material or a furniture material by increasing the commercial value by performing a drying treatment.
[0003]
By the way, as a general drying method of a wooden material, a natural drying method in which the wooden material is left as it is is known. However, the natural drying method requires a long period of 3 to 5 years, and during that time, complicated work such as transshipment of the wooden material is required, so what is an efficient drying method of the wooden material? It's hard to say. Therefore, various methods for drying wood-based materials in place of natural drying methods have been studied.For example, vacuum-drying methods in which wood-based materials are placed in a vacuum environment, or hot-air drying in which hot air is blown into a room containing wood-based materials. Laws have been proposed. However, these drying methods are effective in that the wood-based material can be dried in a short time, but the wood-based material after the drying treatment is cracked or re-absorbs moisture to cause distortion and twist. There is a disadvantage that it occurs.
[0004]
Therefore, recently, a smoke heat treatment method in which high-temperature smoke obtained by burning a wood-based fuel is introduced into a treatment chamber containing a wood-based material, and the wood-based material is treated with the smoke and dried. Is attracting attention. This smoke heat treatment method can dry a wood-based material in a relatively short time due to the cooperation of the temperature of the smoke and various components contained in the smoke, and there are few cracks and distortions. It has the feature that dry woody material can be obtained.
[0005]
As an apparatus for carrying out such a soot heat treatment method, for example, Japanese Patent No. 2516467 and Japanese Patent No. 2540100 disclose a wood storage chamber for storing wood to be dried (an example of a wood-based material). And a wood drying apparatus mainly comprising a combustion gas generation furnace, a combustion gas supply path leading from the top of the combustion gas generation furnace to the top of the wood storage chamber, and a gas discharge path leading from the bottom of the wood storage chamber to the chimney It is disclosed. In this wood drying apparatus, wood waste and the like are burned in a combustion gas generating furnace to generate combustion gas containing smoke. The generated combustion gas flows into the upper part of the wood storage chamber through the combustion gas supply path. The combustion gas that has flowed into the wood storage chamber passes between the woods and flows toward the bottom of the wood storage chamber while drying the wood, and is discharged from the chimney through the gas discharge path.
[0006]
However, the wood-based material processed using this kind of wood drying apparatus is effectively dried in a short time, and thus drying stress may occur in the drying process. Drying stress may cause warping or twisting of the wood-based material, which may impair the commercial value of the wood-based material. In particular, when wood-based materials with a very high water content, such as oil palm raw materials, are dried using this type of wood drying equipment, large amounts of drying stress are generated in the wood-based materials, resulting in complex distortion. Therefore, it is extremely difficult to obtain a dry wood material that can withstand use as a building material.
[0007]
An object of the present invention is to suppress distortion generated in a wood-based material when the wood-based material is smoked and dried by smoke generated by the combustion of the wood-based fuel.
[0008]
[Means for Solving the Problems]
The wood-based material drying apparatus of the present invention is a primary processing device that is set to be able to accommodate a wood-based material and that smokes the wood-based material with smoke generated by the combustion of the wood-based fuel and performs a drying process. And a secondary processing device capable of introducing smoke discharged from the primary processing device, which is set so as to be able to accommodate the wood-based material dried in the processing device. The primary processing apparatus includes a combustion chamber for burning wood-based fuel, a flue for guiding smoke generated in the combustion chamber, which is arranged to extend laterally adjacent to the combustion chamber, and a flue A first material storage chamber for storing a wood-based material having a plurality of openings communicating with the flue at the bottom and a combustion introduced into the first material storage chamber through the flue And a smoke exhaust passage for exhausting smoke from the chamber toward the secondary processing device. In this primary processing apparatus, the bottom of the flue is inclined upward as it moves away from the combustion chamber, and the size of each of the plurality of openings is larger than that of the combustion chamber closer to the combustion chamber. It is set so that the one on the position side away from is gradually larger.
[0009]
When a wood material is dried using this wood material drying device, the wood material is first stored in the primary treatment device, and the wood material is smoked with smoke generated by the combustion of the wood fuel. . As a result, the wood-based material is dried while the growth stress is adjusted and uniformed. Next, the woody material dried in the primary processing apparatus is moved into the secondary processing apparatus, and a new woody material is accommodated in the primary processing apparatus and subjected to the same processing. At this time, the wood-based material accommodated in the secondary processing device is discharged at a lower temperature than that during the drying process in the primary processing device due to the airflow of smoke discharged from the primary processing device and introduced into the secondary processing device. It is dried slowly. As a result, the wood-based material accommodated in the secondary processing apparatus is further dried, and the drying stress generated during the drying process in the primary processing apparatus is adjusted and made uniform.
[0012]
In this wood-based material drying apparatus, the flue gas path has, for example, a flow rate adjusting device for adjusting the flow rate of smoke discharged toward the secondary processing device. Further, the secondary processing device has, for example, an introduction part for introducing smoke discharged from the primary processing device, and a second material for containing the wood-based material dried in the primary processing device. A storage chamber is provided, and the second material storage chamber is disposed higher than the first material storage chamber.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
With reference to FIG. 1 and FIG. 2 (II-II sectional drawing of FIG. 1), the wooden material drying apparatus which concerns on one Embodiment of this invention is demonstrated. In the figure, the wood-based material drying apparatus 100 mainly includes a primary processing apparatus 200 and a secondary processing apparatus 300 for curing the wood-based material processed in the primary processing apparatus 200.
[0014]
As shown in FIG. 3 (III-III sectional view of FIG. 1), the primary processing apparatus 200 mainly includes a combustion chamber 210, a flue 220, a first material storage chamber 230, and a flue gas passage 240. The combustion chamber 210 is for burning wood-based fuel such as wood chips and timber waste, and has an ignition burner 211 for igniting the wood-based fuel. Further, the combustion chamber 210 has a communication hole 212 communicating with the flue 220 at the top, and an intake hole 213 for taking in outside air for combustion. The intake hole 213 includes a damper (not shown) for adjusting the intake air amount.
[0015]
The flue 220 is for guiding the smoke generated in the combustion chamber 210 to the first material storage chamber 230, and is provided adjacent to the combustion chamber 210. The flue 220 extends in the lateral direction (generally in the horizontal direction) from the communication hole 212 of the combustion chamber 210, and inclines upward as the bottom 221 moves away from the combustion chamber 210.
[0016]
The first material storage chamber 230 has a door 231 for storing a wood-based material to be dried (FIG. 1), and is disposed at the upper part of the flue 220. The bottom 232 of the first material storage chamber 230 has a plurality of openings 233 for connecting the flue 220 and the first material storage chamber 230. As shown in FIG. 4 (a plan view of the bottom portion 232), the openings 233 extend in parallel with each other in the width direction of the first material storage chamber 230, and are close to the combustion chamber 210 in size. It is set so that the one on the position side away from the combustion chamber 210 gradually becomes larger than the one. That is, the plurality of openings 233 are set to gradually increase as the distance from the combustion chamber 210 increases.
[0017]
The first material storage chamber 230 includes two shelf boards 234 for placing a wood material to be dried. Each shelf board 234 is horizontally arranged on a number of crosspieces 235 spanned in a lattice form in the horizontal direction in the first material storage chamber 230, and is arranged in the vertical direction. That is, the shelf plates 234 are arranged in multiple stages (two stages in this embodiment) in the vertical direction in the first material storage chamber 230. Here, the lower shelf 234 is arranged in parallel with the bottom 231 with a slight gap 236 from the bottom 232 formed by the thickness of the crosspiece 235. On the other hand, the upper shelf plate 234 is disposed horizontally at a substantially central portion in the height direction of the first material storage chamber 230. Each shelf board 234 used here is a member which has air permeability, for example, is a plate-like member and a net-like member which have many ventilation holes.
[0018]
The first material storage chamber 230 is configured to be airtight so that smoke from the combustion chamber 210 does not leak outside, except for the bottom portion 232 and the flue gas passage 240 portion. The first material storage chamber 230 has a space between the wooden material and the upper shelf 234 or the ceiling of the first material storage chamber 230 when a wooden material is placed on each shelf 234. It is set high enough to be formed.
[0019]
The smoke exhaust passage 240 is for discharging smoke from the combustion chamber 210 introduced into the first material storage chamber 230 to the outside of the first material storage chamber 230. And a chimney collecting path 241, a main flue gas path 242 and a circulation path 243 are mainly provided. The smoke collection path 241 is provided at the center in the width direction of the ceiling portion so as to protrude upward from the ceiling portion of the first material storage chamber 230, and extends in the entire length direction of the ceiling portion.
[0020]
The main smoke exhaust path 242 extends in a direction perpendicular to the secondary processing apparatus 300 from the longitudinal center of the smoke collection path 241 and is a damper for adjusting the amount of exhaust from the first material storage chamber 230. 250 (an example of a flow control device). In addition, the main flue gas passage 242 has a first branch passage 244, a second branch passage 245, and a third branch passage 246 on the side of the secondary processing device 300 (the smoke discharged from the primary processing device 200 in the secondary processing device 300). Branching into three systems (an example of an introduction part for introduction into the system). Each of the branch paths 244, 245, 246 has dampers 247, 248, 249 for adjusting the flow rate of smoke, respectively.
[0021]
The circulation path 243 protrudes from the end of the smoke collection path 241 on the combustion chamber 210 side and branches into two branch paths 251. Each branch passage 251 extends in the width direction of the first material storage chamber 230 and is bent in the direction of the combustion chamber 210, and the tip thereof communicates with the vicinity of the bottom of the combustion chamber 210. That is, an opening 252 communicating with the branch path 251 is provided near the bottom of the combustion chamber 210 (FIG. 3). Each branch passage 251 incorporates a damper (not shown) for adjusting the flow rate of smoke from the smoke collection passage 241.
[0022]
The secondary processing apparatus 300 can store all of the wood-based materials processed simultaneously in the first material storage chamber 230 of the primary processing apparatus 200 and is formed in the same volume and shape as the first material storage chamber 230. The second material storage chamber 310 is provided. As shown in FIG. 2, the second material storage chamber 310 is disposed at a higher position than the first material storage chamber 230. More specifically, the second material storage chamber 310 is arranged such that the position of the bottom is the same as or higher than the height of the ceiling of the first material storage chamber 230, and the wood It has a door 311 for accommodating the system material (FIG. 1). Further, in the second material storage chamber 310, the first branch path 244, the second branch path 245, and the third branch path 246 of the flue gas path 240 are arranged at equal intervals in the vicinity of the bottom of the wall on one end side in the length direction. Contact me. As a result, the first material storage chamber 230 and the second material storage chamber 310 communicate with each other through the smoke exhaust path 240.
[0023]
Further, in the second material storage chamber 310, two shelf boards 312 for placing the wood-based material processed in the first material storage chamber 230 are arranged. Each shelf 312 is horizontally arranged on a large number of bars 313 spanned in a lattice form in the horizontal direction in the second material storage chamber 310 and is arranged in the vertical direction. That is, the shelf boards 312 are arranged in multiple stages (two stages in this embodiment) in the vertical direction in the second material storage chamber 310. Here, the lower shelf plate 312 is disposed above the connection position of the branch paths 244, 245 and 246. On the other hand, the upper shelf plate 312 is horizontally disposed at a substantially central portion in the height direction of the second material storage chamber 310. Each shelf 312 used here is the same as the shelf 234 used in the first material storage chamber 230, that is, a member having air permeability, for example, a plate-like member having a large number of ventilation holes or a net-like member. It is a member.
[0024]
Further, the second material storage chamber 310 has a plurality of the second material storage chambers 310 that protrude upward from the other end side in the length direction, that is, the side opposite to the side where the branch paths 244, 245, 246 communicate with each other In this embodiment, four chimneys 314 are provided.
The second material storage chamber 310 is configured to be airtight so that smoke supplied to the inside from the flue gas passage 240 does not leak outside, except for the connecting portions of the branch passages 244, 245, and 246 and the chimney 314 portion. . The second material storage chamber 310 has a space between the wooden material and the upper shelf 312 or the ceiling of the second material storage chamber 310 when a wooden material is placed on each shelf 312. It is set high enough to be formed.
[0025]
Next, a method for drying a wood-based material using the above-described wood-based material drying apparatus 100 will be described.
First, the wood-based material 400 to be dried is placed in the first material storage chamber 230 of the primary processing apparatus 200. Here, the door 231 is opened, and a large number of wood-based materials 400 are placed on the upper and lower shelf plates 234 from the opening formed thereby. After the wood-based material 400 is accommodated in this way, the door 231 is closed and the first material accommodation chamber 230 is sealed. The woody material 400 that can be dried using the woody material drying apparatus 100 is not particularly limited as long as it is a material obtained by cutting a wooded plant composed of lignocellulose. Timber obtained by cutting trees, palms such as oil palm, and raw materials obtained by cutting plants such as bamboo. Such a wood-based material 400 may have a history of drying processing by a natural drying method or the like. Further, the wood-based material 400 housed in the first material housing chamber 230 is not particularly limited in shape, but is usually a log-shaped material.
[0026]
Next, a wood fuel is disposed in the combustion chamber 210, and the wood fuel is ignited using an ignition burner 211. As a result, the wood fuel is supplied with oxygen by the outside air taken in from the intake hole 213 and burns in the combustion chamber 210. The high-temperature smoke generated as a result of the combustion of the wood fuel continuously flows into the flue 220 through the communication hole 212 as shown by an arrow in FIG. The smoke flowing into the flue 220 does not stay in the vicinity of the communication hole 212 because the bottom portion 221 of the flue 220 is inclined upward as described above, and the flue 220 is guided to the bottom portion 221. Spread throughout.
[0027]
Further, the smoke that has flowed into the flue 220 continuously flows into the first material storage chamber 230 from each opening 233 provided in the bottom 232 of the first material storage chamber 230. Here, each opening 233 is set so that the one on the side farther from the combustion chamber 210 is larger than the one near the combustion chamber 210, so that the smoke in the flue 220 flows into the combustion chamber 210. It is difficult to pass through the opening 233 on the near position side, and it is easy to pass through the opening 233 on the position side away from the combustion chamber 210. Therefore, smoke flows from the respective openings 233 into the first material storage chamber 230 substantially evenly regardless of the distance from the combustion chamber 210. As a result, the inside of the first material storage chamber 230 is almost uniformly filled with smoke from the combustion chamber 210, and the entire temperature is made uniform.
[0028]
Incidentally, the high-temperature smoke filled in the first material storage chamber 230 flows into the main smoke exhaust path 242 while being guided by the smoke collection path 241. Then, the smoke flowing into the main flue gas passage 242 is discharged toward the secondary processing device 300 while the flow rate (the amount of flue gas) is adjusted by the damper 250. A part of the smoke in the smoke collection path 241 flows into the circulation path 243. Smoke that has flowed into the circulation path 243 returns to the combustion chamber 210 from the opening 252 through each branch path 251 and is reburned.
[0029]
Each wooden material 400 stored in the first material storage chamber 230 is smoked by the high-temperature smoke filling the first material storage chamber 230 and dried. That is, each wooden material 400 is dried by smoke heat treatment (primary drying treatment). Here, each wooden material 400 is dried locally because the smoke is uniformly filled in the first material storage chamber 230 and the temperature in the first material storage chamber 230 is uniformized as a whole. There is little risk of being processed, and the drying process is performed almost uniformly. In addition, for the same reason, each wooden material 400 stored in the first material storage chamber 230 is substantially equal to the other wooden material 400 regardless of the arrangement position in the first material storage chamber 230. It is dried. In other words, the wood-based material 400 accommodated in the first material accommodating chamber 230 is substantially equally dried regardless of whether it is disposed near the combustion chamber 210 or disposed away from the combustion chamber 210. Is done. That is, it is difficult for the dry quality to be inhomogeneous between different woody materials 400.
[0030]
Incidentally, even if this primary processing apparatus 200 is a case where the capacity | capacitance of the wood-type material 400 is improved by enlarging the 1st material storage chamber 230, as above-mentioned, a combustion chamber is contained in the 1st material storage chamber 230. Since the smoke from 210 can be uniformly filled, and the temperature in the first material storage chamber 230 can be made uniform as a whole, unlike the conventional smoke heat treatment apparatus, between the wood-based materials 400 The dry quality can be homogenized.
[0031]
In the smoke heat treatment of the wood material 400 in the primary treatment apparatus 200 as described above, the temperature in the first material storage chamber 230, that is, the temperature during the smoke heat treatment of the wood material 400 is usually 100 to 300. It is preferable to set to ° C, and it is more preferable to set to 130 to 150 ° C. When this temperature is less than 100 ° C., it may be difficult to efficiently dry the wood-based material 400 in a short time. On the other hand, when the temperature exceeds 300 ° C., there is a risk that dry cracking or dropping may occur in the wooden material 400 or the strength of the wooden material 400 may decrease.
[0032]
The temperature in the first material storage chamber 230 is controlled by adjusting the intake air amount by the damper of the intake hole 213 in the combustion chamber 210 and adjusting the exhaust gas amount by the damper 250 in the main smoke exhaust passage 242. Can do.
[0033]
In addition, in the above-described smoke heat treatment in the first material storage chamber 230, the moisture content of the wood-based material 400 (moisture content after the primary drying treatment) is usually the moisture content (treatment of the wood-based material 400 before the smoke heat treatment). It is preferable to carry out until it becomes 20 to 40% of the pre-water content). When the moisture content after the primary drying treatment of the wood-based material 400 is set in this manner while setting the temperature during the smoke heat treatment within the above range, the growth stress of the wood-based material 400 can be adjusted and uniformized. The wood-based material 400 can be dried while suppressing distortions such as warping and twisting that occur in the drying process.
[0034]
In addition, the moisture content before a process and the moisture content after a primary drying process are obtained by following Formula (1) and (2), respectively. In the formulas (1) and (2), the weight of the material means the weight of the woody material 400 before the smoke heat treatment. Moreover, in Formula (1), the total dry weight means the weight after carrying out the drying process for 24 hours in the hot air temperature environment of 105 degreeC before the smoke heat processing. Furthermore, in formula (2), the weight after treatment means the weight of the wood-based material 400 after the smoke heat treatment in the first material storage chamber 230.
[0035]
[Expression 1]

[0036]
Incidentally, whether or not the moisture content of the wood-based material 400 has reached the above-mentioned range by the treatment in the primary treatment apparatus 200 is usually determined by the elapsed time and moisture content during the smoke heat treatment for each type of the wood-based material. The relationship with the change can be checked for each set temperature during the smoke heat treatment, and can be determined from the data based on the elapsed time.
[0037]
Next, the wood-based material 400 subjected to the smoke heat treatment in the primary processing apparatus 200 is taken out from the first material storage chamber 230 and transferred to the secondary processing apparatus 300. Here, the door 311 of the second material storage chamber 310 is opened, and the wooden material 400 taken out from the first material storage chamber 230 is placed on each of the upper and lower shelf plates 312 from the opening formed thereby. . After accommodating the wood-based material 400, the second material accommodation chamber 310 closes and seals the door 311.
[0038]
On the other hand, on the primary processing apparatus 200 side from which the wooden material 400 is taken out, a new wooden material 400 is accommodated in the first material accommodation chamber 230. Then, the similar smoke heat treatment is performed on the newly-accommodated wood-based material 400 in the above-described manner.
[0039]
During the smoke heat treatment of the new wood-based material 400 in the primary processing apparatus 200, the high-temperature smoke discharged from the first material storage chamber 230 has a temperature while moving through the main smoke exhaust path 242 of the smoke exhaust path 240. The pressure decreases and flows into the second material storage chamber 310 through the branch paths 244, 245 and 246. The smoke flowing into the second material storage chamber 310 is gradually discharged from the chimney 314 to the outside. Thereby, the airflow by the smoke from the smoke exhaust path 240 passes through the second material storage chamber 310. This airflow flows from one side of the second material storage chamber 310 through the branch paths 244, 245, 246 and is discharged from the chimney 314 provided on the opposite side of the second material storage chamber 310. The entire area 310 is distributed evenly. In addition, the air flow generally heats the inside of the second material storage chamber 310 to a temperature lower than the internal temperature on the first material storage chamber 230 side. As a result, the wood-based material 400 disposed in the second material storage chamber 310 is processed by the smoke airflow in a temperature environment lower than the temperature environment in the first material storage chamber 230, and again dried. (Secondary drying process). Here, the wood-based material 400 is made uniform by adjusting the drying stress generated during the smoke heat treatment in the first material storage chamber 230, and distortions such as warping and twisting are further suppressed. That is, the wood-based material 400 is further dried in the secondary processing apparatus 300 in a mild temperature environment as compared with the case of the primary processing apparatus 200, thereby further increasing the degree of drying, and at the same time, warping and Twisting is further suppressed and it becomes homogeneous. In other words, in the secondary processing apparatus 300, it is possible to obtain a wood-based material 400 with less distortion such as warping and twisting and having a high degree of drying.
[0040]
The airflow passing through the second material storage chamber 310 is controlled by adjusting the dampers 247, 248, and 249 of the branch paths 244, 245, and 246, thereby controlling the inflow amount of smoke. It can be distributed more uniformly within. Further, by adjusting the dampers 247, 248, and 249, the temperature in the second material storage chamber 310 can be made more uniform as a whole. Therefore, the wood-based material 400 accommodated in the second material accommodation chamber 310 can be uniformly dried as a whole regardless of the arrangement position.
[0041]
Further, in the secondary drying process of the wood-based material 400 in the secondary processing apparatus 300, airflow is generated in the second material storage chamber 310 using the flue gas from the primary processing apparatus 200 and the second material storage chamber. Since the inside 310 is heated, the wood-based material 400 can be economically subjected to secondary drying.
[0042]
The processing of the wood material 400 by the secondary processing apparatus 300 is performed by setting the temperature in the second material storage chamber 310, that is, the temperature at the time of the secondary drying treatment of the wood material 400 to 60 to 90 ° C. Is preferable, and it is more preferable to set the temperature at 70 to 80 ° C. When this temperature is less than 60 ° C., the degree of drying of the wood-based material 400 is difficult to increase, and the drying stress generated in the wood-based material 400 during the primary drying process may not be uniformed. On the other hand, when the temperature exceeds 90 ° C., the wood-based material 400 becomes overdried and a new drying stress is generated, which may cause a deviation during the sawing.
[0043]
Incidentally, since the temperature of the smoke from the first material storage chamber 230 is usually lowered while the temperature in the second material storage chamber 310 is moving through the main flue path 242, the smoke is transferred to the second material storage chamber 310. When installed in 310, it can be set to the above range.
[0044]
In addition, the treatment of the wood-based material 400 by the secondary treatment apparatus 300 usually has a moisture content of the wood-based material 400 (moisture content after the secondary drying treatment) that is the moisture content of the wood-based material 400 before the smoke heat treatment (described above). It is preferable to carry out until it becomes 5 to 15% of the water content before treatment. When the moisture content after the secondary drying treatment of the wood-based material 400 is set in this manner while setting the temperature during the secondary drying treatment within the above range, the drying stress generated in the wood-based material 400 is adjusted more effectively. Thus, it is possible to obtain a wood-based material 400 in which distortion such as warping and twisting is more effectively suppressed.
[0045]
In addition, the water content after a secondary drying process is obtained by following Formula (3). In the formula (3), the weight after secondary processing means the weight of the wood-based material 400 after processing in the second material storage chamber 310.
[0046]
[Expression 2]

[0047]
Incidentally, whether or not the moisture content of the wood-based material 400 has reached the above-mentioned range by the processing in the secondary treatment apparatus 300 is usually based on the relationship between the elapsed time and the moisture content change for each type of wood-based material. A check can be made for each set temperature in the secondary processing apparatus 300, and determination can be made based on the elapsed time from the data.
[0048]
The wood-based material 400 subjected to the secondary drying process in the secondary processing apparatus 300 has soot attached to the surface due to the smoke heat treatment, and therefore, after removing the surface as necessary, the wood-based material 400 is appropriately cut and cut into building materials or Used as furniture material.
[0049]
[Other embodiments]
(1) In the above-described embodiment, the shelf plates 234 are arranged in two stages in the first material storage chamber 230, and the wooden material 400 can be stored in two stages in the vertical direction. It is also possible to arrange three or more plates 234 so that the wood-based material 400 can be stacked and accommodated in three or more steps. Moreover, the shelf board 234 does not necessarily need to be arrange | positioned in two or more steps | paragraphs, and can also be comprised so that the wood-type raw material 400 may be located in a line with a horizontal direction.
[0051]
(2) In the above-described embodiment, the wood fuel disposed in the combustion chamber 210 is ignited by using the ignition burner 211. However, the wood fuel is ignited by introducing a fire type into the combustion chamber 210. You can also.
[0052]
【The invention's effect】
The wood-based material drying apparatus of the present invention includes the primary processing apparatus as described above and a secondary processing apparatus capable of introducing smoke discharged from the primary processing apparatus. When the wood-based material is soaked and dried with the smoke generated by the above, the wood-based material can be efficiently dried and the distortion generated in the wood-based material can be suppressed. Therefore, if this woody material drying apparatus is used, a dry woody material with less distortion such as warping and twisting can be obtained.
[Brief description of the drawings]
FIG. 1 is a schematic plan view of a wood-based material drying apparatus according to an embodiment of the present invention.
2 is a cross-sectional view taken along the line II-II in FIG.
3 is a cross-sectional view taken along the line III-III in FIG.
FIG. 4 is a plan view of a bottom portion of a first material storage chamber of a primary processing apparatus employed in the wood material drying apparatus.
[Explanation of symbols]
100 Woody Material Drying Device 200 Primary Processing Device 210 Combustion Chamber 220 Flue 221 Bottom 230 First Material Storage Chamber 232 Bottom 233 Opening 240 Smoke flue 244 First branch 245 Second branch 246 Third branch 250 Damper 300 Secondary processing device 310 Second material storage chamber 400 Wood material

Claims (3)

A primary processing device configured to contain a wood-based material, and smokes the wood-based material with the smoke generated by the combustion of the wood-based fuel to dry the wood-based material;
A secondary treatment device capable of introducing the smoke discharged from the primary treatment device, set to be able to accommodate the wood-based material dried in the primary treatment device ,
The primary processing device includes a combustion chamber for burning the wood fuel, and smoke for guiding the smoke generated in the combustion chamber, which is disposed to extend laterally adjacent to the combustion chamber. A first material storage chamber for storing the wood-based material, which is disposed at the top of the flue and has a plurality of openings formed at the bottom to communicate with the flue; and through the flue And a flue gas passage for discharging the smoke from the combustion chamber introduced into the first material storage chamber toward the secondary processing device, and the bottom of the flue rises as the distance from the combustion chamber increases Each of the plurality of openings is set so that the size on the side farther from the combustion chamber is gradually larger than that on the side closer to the combustion chamber.
Wood material drying equipment.   The wood-based material drying apparatus according to claim 1, wherein the flue gas passage has a flow rate adjusting device for adjusting a flow rate of the smoke discharged toward the secondary processing device.   The secondary processing device has an introduction part for introducing the smoke discharged from the primary processing device, and a second for containing the wood-based material dried in the primary processing device. The woody material drying apparatus according to claim 1 or 2, further comprising a material storage chamber, wherein the second material storage chamber is disposed at a higher position than the first material storage chamber.

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