JP2010159943A - Chip dryer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small chip dryer capable of effectively drying vegetable chips. <P>SOLUTION: In the chip dryer 1, a storage and drying chamber 21 having opposing two inner faces 21a, 21a inclined in directions reverse to each other and formed to have an approximately box shape wide toward the end and a carrying front chamber 23 are provided within a pentagon casing 2 rectangular in front face view and vertically long in side face view. An air supply body 3 for supplying heating gas to the storage and drying chamber 21 is arranged within the storage and drying chamber 21. The air supply body 3 is arranged to cross inside of the storage and drying chamber 21 in the width direction, and includes two net bodies 31, 31 arranged approximately in parallel with the two inner faces 21a, 21a of the storage and drying chamber 21 and provided on the surface. The net bodies 31, 31 of the air supply body 3 are inclined in directions reveres to each other, and arranged to become wide toward the end in the cross section. The heating gas is supplied to inside of the air supply body 3 via heating piping connected to the lateral face of the casing 2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a chip drying apparatus that dries vegetable chips used for fuel, for example.

  Recently, plant biomass fuel has attracted attention in order to cope with problems such as an increase in the concentration of carbon dioxide in the atmosphere and an increase in the price of fossil fuels.

  Plant biomass fuel is considered to be carbon neutral because the amount of carbon dioxide generated by combustion is considered to be substantially the same as the amount of carbon dioxide absorbed by the plant as a material during the growth process. For this reason, it can respond effectively to the carbon dioxide emission regulation, and is advantageous in the emission trading.

  As plant biomass fuel, wooden chips made of building waste, thinned wood, etc., which have been conventionally discarded as industrial waste, have attracted attention because of their relatively low manufacturing costs. When the raw material such as thinned wood is a material, the wood chip has a relatively high moisture content of around 50%. Therefore, it is necessary to reduce the moisture content to about 10% before using it as fuel. Conventionally, there is a device using a rotary kiln as a device for drying wood chips. This type of rotary kiln includes a rotary furnace in which wood chips are introduced from one end, and the introduced wood chips are agitated by rotating operation to the other end, and a burner that emits flame into the rotary furnace using oil as fuel. (For example, refer to Patent Document 1; JP-A-2002-088373).

JP 2002-088373 A

  However, when a rotary kiln is used for drying wood chips, the rotary kiln has a rotary furnace that performs a stirring operation and a feeding operation of the wood chips by a rotating operation, and there is a problem that the drying apparatus is enlarged. If the drying device is large, when the boiler device is configured in combination with a boiler using wood chips as a fuel, there is a problem that the boiler device becomes large.

  Moreover, since the rotary kiln uses the flame of the burner as a heat source, there is a problem that the inside of the rotary furnace tends to become high temperature, and it is difficult to adjust the wood chip to an appropriate drying degree according to the water content. In particular, when drying wood chips having a low water content made from building waste, the inside of the rotary furnace is hot, so that it is easily carbonized and is not suitable for drying wood chips.

  In addition, when a rotary kiln is used for drying wood chips, the rotary kiln uses a burner as a heat source for drying the material, so fossil fuel is used to produce plant biomass fuel, and carbon neutral of plant biomass fuel is used. There is a problem that the effect is reduced.

  Then, the subject of this invention is providing the small chip drying apparatus which can dry a vegetable chip | tip effectively. Another object of the present invention is to provide a chip drying device that can appropriately adjust the degree of drying according to the moisture content of the chip. It is another object of the present invention to provide a chip drying apparatus that can prevent emission of carbon dioxide in the production process and can produce vegetable chip fuel without reducing the effect as carbon neutral.

In order to solve the above problems, the chip drying apparatus of the present invention includes a storage drying chamber in which the lower cross-sectional area is larger than the upper cross-sectional area;
A chip insertion port provided at the top of the storage drying chamber;
Arranged in the storage / drying chamber, the upper cross-sectional area is formed smaller than the lower cross-sectional area, and the heated gas supplied to the inside at the lower part is guided upward, and from the outlet provided on the surface into the storage / drying chamber. A heated gas distributor that blows out;
A discharge section for discharging chips from the storage drying chamber;
And a transport unit that transports the chips discharged by the discharge unit.

  According to the said structure, a vegetable chip | tip is thrown in in a storage drying chamber from a chip | tip insertion port. The chip thrown into the storage / drying chamber is dried by the heated gas blown out from the air outlet on the surface of the heated gas distributor. The dried chips are discharged from the storage / drying chamber by the discharge unit, and the discharged chips are transferred to, for example, a boiler by the transfer unit and used as fuel for the boiler or the like.

  This chip drying apparatus dries the chips introduced from the upper inlet into the storage / drying chamber with the heated gas blown out from the heated gas distribution unit until it is discharged from the discharge unit at the lower part of the storage / drying chamber. As with a rotary kiln, the size can be reduced as compared with a rotary furnace that performs a feeding operation while stirring the chip in a state where the flame of the burner is radiated inside. Therefore, when this chip drying apparatus is combined with, for example, a boiler using a chip as a fuel to constitute a boiler apparatus, the boiler apparatus can be effectively downsized.

  Moreover, since this chip drying apparatus dries the chip in the storage / drying chamber with the heated gas blown out from the heated gas distribution unit, the drying capacity is determined by the discharge speed of the chip by the discharge unit and the heating gas from the heated gas distribution unit. It can be easily adjusted by adjusting the temperature and flow rate. Therefore, since the drying capacity can be easily adjusted according to the moisture content of the chip, for example, plant biomass chips formed from materials with different moisture content such as building waste with low moisture content and thinned wood with high moisture content, It can be stably dried to a predetermined water content.

  Further, this chip drying apparatus has a housing drying chamber in which the lower cross-sectional area is larger than the upper cross-sectional area, so that the chip inside can be smoothly moved downward, and chip clogging and bridging Can be effectively prevented. In particular, when the vegetable chip is a wood chip, the shape is irregular with many corners, and although the bridge is relatively easy to occur, the above-described drying chamber prevents the generation of the bridge, so that Chips can be dried and discharged.

In the chip drying apparatus according to an embodiment, the storage drying chamber is formed in a substantially box-like shape that spreads in the opposite direction with two inner side surfaces facing each other inclined in opposite directions,
The heated gas distribution part is disposed substantially parallel to the two inner side surfaces of the storage drying chamber and has two nets inclined in opposite directions on the surface,
The discharge part is disposed in the vicinity of the lower end edges of the two mesh bodies of the heated gas distribution part, and is formed by two rotating blades that are driven to rotate around a rotation axis parallel to the lower end edges of the mesh bodies,
The said conveyance part has the screw conveyor arrange | positioned substantially parallel to a rotary blade below the two rotary blades of the said discharge part.

  According to the above-described embodiment, the storage / drying chamber is formed in a substantially box-like shape with two opposite inner surfaces inclined in opposite directions, and the heated gas distribution portion in the storage / drying chamber is formed in the storage / drying chamber. Since the surface has two nets arranged substantially parallel to the two inner side surfaces and inclined in opposite directions, a chip drying device that can dry the chip while preventing clogging and bridging can be obtained. .

  In addition, by arranging the two rotating blades in the vicinity of the lower edges of the two mesh bodies inclined in opposite directions of the heated gas distribution section, a space with a relatively wide depth below the storage drying chamber is effective. By utilizing this, the discharge portion can be arranged without enlarging the entire depth. Accordingly, the chip drying can be effectively adjusted by the discharge unit in a thin portion, that is, the residence time in the chip housing and drying chamber can be effectively adjusted, and the degree of drying of the chip can be adjusted flexibly while being thin. A device is obtained.

  In the chip drying apparatus according to an embodiment, the heated gas distribution unit includes an air supply unit that supplies heated gas between the mesh bodies, and a rectifier that distributes the heated gas supplied from the air supply unit in the width direction of the network body. A board.

  According to the above embodiment, the heated gas distribution unit distributes the heated gas supplied between the mesh bodies by the air supply unit in the width direction of the mesh body by the rectifying plate, so that heating is uniformly performed from the mesh body in the width direction. The gas can be blown into the storage / drying chamber, and thus the chips in the storage / drying chamber can be dried without being biased while being thin.

  In the chip drying apparatus according to an embodiment, the screw conveyor of the transfer unit is formed at an unequal pitch that increases in pitch as the screw advances in the chip carry-out direction.

  According to the embodiment, since the pitch of the screw is formed so as to advance in the chip carry-out direction in the extending direction of the screw conveyor corresponding to the width direction of the storage drying chamber, the screw conveys the chip. Accordingly, the amount of chips transferred can be increased, and thus the chips discharged from the storage / drying chamber by the discharge unit can be uniformly transferred in the width direction. As a result, it is possible to discharge chips uniformly in the width direction from the wide storage / drying chamber while the entire width direction is longer than the depth direction, and therefore, the chips in the storage / drying chamber are not biased. Can be dried.

In the chip drying device of one embodiment, the storage drying chamber is formed in a truncated cone shape,
The heated gas distribution section has a frustoconical side-surface-shaped net disposed coaxially with the frustoconical storage drying chamber on the surface,
The discharge part is formed by rotating blades that are arranged radially at the bottom of the frustoconical storage drying chamber and are driven to rotate around the central axis of the circular bottom surface of the storage drying chamber,
The conveyance unit includes a screw conveyor that is disposed below the rotary blades of the discharge unit and extends in a tangential direction of an arc drawn by a tip of the rotary blades in plan view.

  According to the above-described embodiment, the storage / drying chamber is formed in a truncated cone shape, and the heated gas distribution portion in the storage / drying chamber is arranged in the shape of the truncated cone side surface disposed coaxially with the truncated cone-shaped storage / drying chamber. Therefore, a chip drying apparatus that can dry the chip while preventing clogging and bridging while being vertically long and small is obtained.

  In addition, by arranging the rotating blades radially at the bottom of the frustoconical storage / drying chamber, a relatively wide space at the bottom of the storage / drying chamber having a circular shape can be effectively used without increasing the overall diameter. A discharge part can be arranged. Therefore, while being vertically long and small, the discharge amount of the chip can be effectively adjusted by the discharge unit, that is, the residence time in the chip accommodating and drying chamber can be effectively adjusted, and the degree of drying of the chip can be flexibly adjusted. A chip drying apparatus is obtained.

  In addition, since the transport unit has a screw conveyor that is arranged below the rotary blades of the discharge unit and extends in the tangential direction of the arc drawn by the tip of the rotary blades in plan view, the transport unit without increasing the overall diameter Can be arranged.

The chip drying apparatus of one embodiment includes a disk member at the bottom of the storage drying chamber,
The heated gas distribution part and the rotating blade are fixed to the surface of the disk member,
As the disk member is driven to rotate, the heated gas distributor and the rotating blades are formed to rotate about a concentric axis.

  According to the above embodiment, by rotating the disk member, the heated gas distribution unit and the rotating blades are rotationally driven, and the heating gas is supplied from the heated gas distribution unit to the chip without any bias to dry the chip without bias. In addition, the chips can be discharged toward the screw conveyor without being biased in the circumferential direction by the rotating blades.

The chip drying apparatus of one embodiment includes a pre-transport chamber for temporarily storing the chips discharged from the discharge unit before being transported by the transport unit;
A chip amount sensor for detecting the amount of chips in the pre-transport chamber;
A discharge control unit that controls the operation of the discharge unit based on the detection signal of the chip amount sensor.

  According to the above-described embodiment, the chips discharged from the storage / drying chamber by the discharge unit are temporarily stored in the pre-transfer chamber, and the chips stored in the pre-transfer chamber are transferred by the transfer unit. Based on the amount of chips in the pre-conveyance chamber detected by the chip amount sensor, the operation of the discharge unit is controlled by the discharge control unit. For example, when the amount of chips in the chamber before transfer is small, the discharge amount of the chips to the chamber before transfer by the discharge unit is controlled to increase. On the other hand, when the amount of chips in the pre-conveyance chamber is large, control is performed so that the discharge amount of the chips to the pre-conveyance chamber by the discharge unit is reduced or stopped. As a result, the amount of stored chips in the pre-conveyance chamber is stabilized, so that the amount of chips transported by the transport unit can be stabilized. Therefore, when conveying a chip | tip as a fuel from a conveyance part, for example to the burner of a boiler, a fuel can be stably and quantitatively supplied to a burner.

The chip drying apparatus of one embodiment includes a moisture sensor for detecting the moisture content of the chip in the storage drying chamber,
A drying control unit that controls the operation of the discharge unit based on the detection signal of the moisture sensor.

  According to the above embodiment, the moisture content of the chip in the storage / drying chamber is detected by the moisture sensor, and the operation of the discharge unit is controlled by the drying controller based on the detection signal of the moisture sensor. For example, when the moisture content of the chip in the storage / drying chamber is small, the discharge amount by the discharge unit is controlled to increase. On the other hand, when the moisture content of the chip in the pre-conveyance chamber is large, the discharge amount of the chip by the discharge unit is controlled to be reduced or stopped. Thus, since the residence time of the chip | tip in a storage drying chamber can be adjusted appropriately according to the moisture content of a chip | tip, the time which exposes heating gas to a chip | tip can be adjusted appropriately. As a result, even when chips having different moisture contents are put into the storage / drying chamber, the drying capacity can be adjusted flexibly according to the moisture content of the chips, and the chips can be stably dried to a predetermined moisture content.

  In the chip drying apparatus according to an embodiment, the heated gas is a burner combustion gas using the chip transported from the transport unit as fuel.

  According to the above embodiment, since the chip is dried using the combustion gas of the burner that uses the chip dried by this chip drying apparatus as a fuel, it is compared with the case where the chip is dried using the heat generated by the fossil fuel. Thus, the effect of the plant biomass fuel as carbon neutral is not diminished, and therefore, the chips dried by this chip drying apparatus can substantially reduce the carbon dioxide emission.

  According to the present invention, the heated gas distributor is disposed in the storage / drying chamber having the chip inlet at the top, the lower cross-sectional area of the storage / drying chamber is formed larger than the upper cross-sectional area, and the heated gas distribution unit The upper gas cross-sectional area is formed smaller than the lower cross-sectional area, and the heated gas distribution section guides the heated gas supplied to the inner side at the lower part and accommodates it from the air outlet provided on the surface. Since it blows out into a drying chamber, a small chip drying apparatus is obtained. In addition, the drying capacity can be easily adjusted by adjusting the discharge speed of the discharge section for discharging the chips from the storage drying chamber and the temperature or flow rate of the heated gas from the heated gas distribution section. By adjusting the drying capacity, the chip can be stably dried to a predetermined water content. Furthermore, since the storage drying chamber has a lower cross-sectional area larger than the upper cross-sectional area, it is possible to smoothly move the chip inside and to prevent chip clogging and bridging. Can be prevented.

It is a longitudinal cross-sectional view which shows the chip drying apparatus of 1st Embodiment. It is a cross-sectional view of the chip drying apparatus of 1st Embodiment. It is a longitudinal cross-sectional view which shows the chip drying apparatus of 2nd Embodiment. It is a plane sectional view of the chip drying device of a 2nd embodiment.

  Hereinafter, embodiments of a chip drying apparatus of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a longitudinal sectional view showing a chip drying apparatus according to a first embodiment of the present invention, and FIG. 2 is a transverse sectional view of the chip drying apparatus.

  The chip drying apparatus of the first embodiment dries a wood chip as a plant chip. This chip drying device is combined with a boiler using dried wood chips as fuel, and is installed at a position close to this boiler.

  This chip drying apparatus 1 has an accommodating / drying chamber 21 and a pre-conveyance chamber 23 in a pentagonal casing 2 that is rectangular in front view and vertically long in side view. At the upper end of the casing 2, a chip insertion port 2 a communicating with the storage / drying chamber 21 is provided.

  The storage / drying chamber 21 is formed in the upper half of the casing 2 and is formed in a substantially box-like shape in which two opposing inner side surfaces 21a, 21a incline in opposite directions and spread outwardly. Thereby, the lower cross-sectional area is formed larger than the upper cross-sectional area. A tip end portion of a chip supply pipe 22 for supplying the chip T to the storage / drying chamber 21 is inserted into the chip insertion port 2a.

  In the storage / drying chamber 21, a supply gas 3 is disposed as a heated gas distribution unit that supplies heated gas to the storage / drying chamber 21. The supply gas 3 is disposed across the inside of the storage / drying chamber 21 in the width direction, and two nets 31, 31 substantially parallel to the two inner side surfaces 21 a, 21 a of the storage / drying chamber 21 are provided on the surface. . The nets 31, 31 of the supply gas 3 are inclined in opposite directions to each other, and are arranged so as to widen toward the end in the cross section. The upper ends of the two nets 31, 31 are connected to each other by a gable-type upper end net 32 that is located below the tip of the tip supply pipe 22 inserted into the inlet 2 a of the casing 2 and is gently inclined. Yes. The tip T discharged from the tip of the tip supply pipe 22 is distributed to both sides of the two nets 31 by the gable-type upper end net 32. Inside the upper end net 32 and the two nets 31, 31, a heated gas passage is formed.

  A heating pipe 4 is connected to the side surface of the casing 2, and the heating gas is supplied into the supply gas 3 through the heating pipe 4. A plurality of dampers 5, 5,... Are provided inside the connection portion of the heating pipe 4 with the casing 2. A plurality of rectifying plates 6, 6,... Are provided from the position where the damper 5 is disposed toward the inside of the supply gas 3. It is formed so that the flow rate of the heated gas flowing between the rectifying plates 6, 6,. The rectifying plates 6, 6,... Extend horizontally from the position where the damper 5 is disposed and reach the inside of the supply gas 3, and the horizontal portions 6 a, 6 a,. .. Have vertical portions 6b, 6b,... The vertical portions 6b, 6b,... Of the rectifying plates 6, 6,... Are arranged at equal intervals in the width direction in the supply gas 3, thereby supplying the heated gas from the heating pipe 4 to the supply gas. 3 is formed so as to be uniformly distributed in the width direction.

  Below the two mesh bodies 31, 31 of the supply gas 3, two cylindrical rotary blades 7, 7 are arranged as two discharge portions extending along the lower end edge of the mesh body 31. The rotary blade 7 is disposed in a gap between the lower end edge of the mesh body 31 and the partition plate 24 that defines the bottom surface of the storage drying chamber 21. The rotary blades 7 are rotationally driven in opposite directions toward the inside of the storage / drying chamber 21 as indicated by arrows A and A, whereby the tip T in the storage / drying chamber 21 is moved to the lower end edge of the net 31. It is formed so as to be discharged from the space between the rotary blades 7 to the front chamber 23.

  The front chamber 23 has a substantially inverted triangular shape in cross section, and a screw conveyor 8 extending in parallel with the rotary blades 7 is formed at the apex at the lower end. The front chamber 23 has the same width as the storage / drying chamber 21 in a front view and is disposed below the storage / drying chamber 21. The screw conveyor 8 extends over the entire width of the pre-conveyance chamber 23 and protrudes in the extending direction from one end in the width direction of the pre-conveyance chamber 23. A chip discharge port 81 is provided on the lower surface of the protruding portion of the screw conveyor 8. The screw conveyor 8 includes a rotating shaft 82 that receives a rotational force from a motor (not shown), and a spiral blade 83 that is fixed around the rotating shaft 82. The spiral blades 83 are formed at unequal pitches whose pitches increase in the direction in which the chips T are transported. Thereby, as it approaches the discharge port 81, more chips T are transported, and the chips T are transported uniformly in the width direction of the pre-transport chamber 23.

  The discharge port 81 of the screw conveyor 8 is connected to a fuel conveyor of a boiler (not shown), and is formed so that the chip T discharged from the discharge port 81 is supplied to the boiler burner through the fuel conveyor. A part of the combustion gas of the boiler burner is formed to be supplied to the heating pipe 4 as shown by an arrow G through a gas pipe (not shown). As described above, the chip drying apparatus 1 dries the chip T and supplies it to the boiler as fuel, and uses a part of the combustion gas obtained by burning the chip T in the boiler as the heating gas. .

  The operation of the rotary blades 7 and 7 serving as discharge units for discharging the chips T from the storage drying chamber 21 to the pre-transport chamber 23 is controlled by a control unit (not shown). The control unit controls the operation of the rotary blades 7 and 7 based on the detection signal from the moisture sensor S1 installed in the storage / drying chamber 21 and the detection signal from the chip amount sensor S2 installed in the front chamber 23. And function as a discharge control unit and a drying control unit. Further, the control unit is formed to control the operation of the screw conveyor 8 based on the detection signal from the chip amount sensor S2.

  The moisture sensor S1 is provided on the inner wall surface of the storage / drying chamber 21, emits near-infrared light, receives reflected light, and detects the amount of moisture by detecting absorption at a predetermined wavelength of near-infrared light by moisture. It is an optical moisture sensor to be measured. The moisture sensor S1 detects the water content of the chip T stored in the storage / drying chamber 21. The moisture sensor S1 may be one that measures the dielectric constant of the chip T or one that measures the electrical conductivity of the chip T in addition to the one that uses near infrared light.

  The chip amount sensor S2 has an infrared emitting part provided on the upper part of the inner wall surface of the pre-carrying chamber 23, and an infrared light receiving part provided on the inner wall surface facing the inner wall surface provided with the infrared emitting part. Whether the amount of chips T stored in the pre-transport chamber 23 exceeds the height of the infrared emitting section and the amount of light received by the infrared light receiving section decreases, so that a predetermined amount of chips T exists in the pre-transport chamber 23 It is configured to detect whether or not. Note that the chip amount sensor 2 may detect the phase difference of reflected light formed by emitting a plurality of infrared rays to the chip surface and measure the height of the chip surface. In addition to infrared rays, the chip amount may be measured using ultrasonic waves.

  The chip drying apparatus 1 according to the first embodiment operates as follows.

  First, the tip T is supplied to the storage / drying chamber 21 through the tip supply pipe 22, and the dampers 5, 5,... Are opened, and the combustion gas as the heating gas is supplied from the boiler to the heating pipe 4.

  The chip T discharged from the chip supply pipe 22 is distributed to both sides of the two net bodies 31 by the upper end net 32 of the supply gas 3, and the inner surfaces 21 a and 21 a of the supply gas 3 and the accommodating drying chamber 21. Is housed between.

  The heated gas supplied to the heating pipe 4 is rectified by the rectifying plates 6, 6,... And is uniformly distributed in the supply gas 3 in the width direction. The heated gas in the supply gas 3 flows to the chips T on both sides of the supply gas 3 through the nets 31 and 31, and the chips T are heated to evaporate moisture. The heated gas that has heated the chip T contains moisture evaporated from the chip T and is discharged to the outside from the chip insertion port 2a.

  When the chip T is dried and the moisture sensor S1 detects that the water content of the chip T is below a predetermined reference value, the rotary blades 7 and 7 are activated by the control of the control unit, and the chip in the storage drying chamber 21 is activated. Is discharged into the pre-transport chamber 23. When it is detected by the chip amount sensor S2 that the amount of chips T in the pre-conveyance chamber 23 exceeds a predetermined amount, the screw conveyor 8 is activated by the control of the control unit, and the chips T are conveyed from the pre-conveyance chamber 23. Then, the chip T is delivered from the discharge port 81 to a fuel conveyor of a boiler (not shown).

  When the chip T in the storage / drying chamber 21 is discharged and the chip T is newly discharged from the chip supply pipe 22 and the water content of the chip T exceeds the reference value, the rotational speed of the rotary blades 7 and 7 is controlled by the control unit. Is reduced or stopped. As a result, the residence time in the storage / drying chamber 21 becomes longer, or the chip T stays in the storage / drying chamber 21 and is sufficiently heated by the heated gas to promote drying. When the tip T is dried and the moisture sensor S1 detects that the moisture content is below a predetermined reference value, the rotation speed of the rotary blades 7 and 7 is increased or stopped by the control of the control unit. The blades 7 and 7 are activated, and the chip T is discharged from the storage / drying chamber 21 to the pre-transport chamber 23. As described above, the operation of the rotary blades 7 and 7 is controlled by the control unit according to the water content of the chip T in the storage / drying chamber 21. Therefore, even if chips T having different moisture contents are supplied, such as chips formed from building waste materials having a low water content or thinned wood materials having a high water content, the water content of the chips T will be adjusted. Thus, the drying time can be adjusted, and chips having a predetermined water content can be obtained stably.

  During the operation of the screw conveyor 8, when the tip amount sensor S2 detects that the amount of chips in the pre-conveyance chamber 23 has fallen below a predetermined amount, the rotational speed of the rotary blades 7 and 7 increases under the control of the control unit. Is done. Moreover, when the rotary blades 7 and 7 are stopped, the rotary blades 7 and 7 are activated by the control of the control unit. Thereby, the discharge amount of the chip T from the storage / drying chamber 21 to the pre-transport chamber 23 is increased, the amount of the chip T in the pre-transport chamber 23 is increased, and the storage amount of the chip T in the pre-transport chamber 23 is stabilized. . Therefore, the conveyance amount of the chip T by the screw conveyor 8 can be stabilized, and fuel can be stably supplied to the burner of the boiler.

  The chip drying apparatus 1 according to the present embodiment is configured to supply gas during a period from when the chips loaded into the storage / drying chamber 21 through the chip supply pipe 22 through the inlet 2a are discharged from the storage / drying chamber 21 by the rotary blades 7 and 7. Since it dries with the heated gas blown out from 3, it can be made smaller than a rotary kiln equipped with a rotary furnace. Therefore, even if this chip drying apparatus 1 comprises a boiler apparatus combining with the boiler which uses the chip | tip T as a fuel, a boiler apparatus can be reduced in size effectively.

  Moreover, since this chip drying apparatus 1 dries the chip T in the storage drying chamber 21 with the heated gas blown out from the supply gas 3, the chip T can be adjusted by adjusting the residence time of the chip T in the storage drying chamber 21. Can easily adjust the drying capacity of Therefore, since the drying capacity can be easily adjusted according to the moisture content of the chip T, plants with a predetermined moisture content can be prepared using materials with different moisture content such as building waste materials with low moisture content and thinned wood with high moisture content. Biomass chips can be manufactured stably and easily. Note that the drying capacity of the chip drying device 1 may be adjusted by adjusting the temperature and flow rate of the heated gas from the supply gas 3.

  Further, in the chip drying apparatus 1, since the housing / drying chamber 21 is formed such that the lower cross-sectional area is larger than the upper cross-sectional area, the inner chip T can be smoothly moved downward. Therefore, although the wood chip is an irregular shape with many corners and the bridge is relatively easy to be generated, the accommodation drying chamber 21 can prevent the bridge from being generated, so that the chip T can be smoothly dried and discharged. Can do.

  Further, the chip drying apparatus 1 is configured such that the storage / drying chamber 21 is formed in a substantially box-like shape with two inner side surfaces 21a and 21a facing each other in a divergent shape in which they are inclined in opposite directions. Are arranged in parallel with the two inner side surfaces 21a, 21a of the storage / drying chamber 21 and are inclined in opposite directions to prevent clogging or bridging while being thin. However, the chip T can be dried.

  In addition, since the two rotary blades 7 and 7 are arranged in the vicinity of the lower end edges of the two net bodies 31 and 31 inclined in opposite directions of the supply gas 3, respectively, the lower depth of the storage drying chamber 21 is compared. It is possible to arrange the rotary blades 7 and 7 without increasing the overall depth by effectively using a large space. Therefore, the chip drying apparatus 1 can effectively adjust the discharge amount of the chip T with the rotary blades 7 and 7 while being thin, that is, effectively adjust the residence time of the chip T in the accommodation drying chamber 21. Thus, the degree of drying of the chip T can be adjusted flexibly.

  FIG. 3 is a longitudinal sectional view showing a chip drying apparatus according to a second embodiment of the present invention, and FIG. 4 is a plan sectional view of the chip drying apparatus.

  The chip drying apparatus 101 has a housing / drying chamber 121 in a substantially frustoconical casing 102, and a chip insertion port 102 a communicating with the housing / drying chamber 121 is provided at the upper end of the casing 102.

  The storage drying chamber 121 is formed in the upper half of the casing 102, and the inner side surface 121a is formed in a side shape of an inverted truncated cone. Thereby, the lower cross-sectional area is formed larger than the upper cross-sectional area. A tip end portion of a chip supply pipe 122 that supplies the chip T to the storage / drying chamber 121 is inserted into the chip insertion port 102a.

  In the storage / drying chamber 121, an air supply tower 103 is disposed as a heated gas distribution unit. The air supply tower 103 has a substantially truncated cone shape coaxial with the casing 102, and includes a side net 131 and an upper end net 132 connected to the upper end of the side net 131. The side net 131 has a truncated conical side shape, whereby the air supply tower 103 is formed such that the lower cross-sectional area is larger than the upper cross-sectional area. The upper end mesh 132 has a conical side surface shape with a gentler slope than the side mesh 131. The tip T discharged from the tip of the tip supply pipe 122 is uniformly distributed around the side net 131 by the upper side net 132 having a conical side shape. Heated gas passages are formed inside the upper end mesh 132 and the side net 131.

  At the bottom of the storage / drying chamber 121, a disk member 110 having a slightly smaller diameter than the bottom surface of the storage / drying chamber 121 is provided, and the air supply tower 103 is coaxially fixed to the upper surface of the disk member 110. On the upper surface of the disk member 110, rotary blades 107 as discharge portions are arranged radially.

  A cylindrical air box 111 is provided at the lower end of the casing 102, and a heating pipe 104 is connected to a side surface of the air box 111. The heating gas is formed so as to be supplied into the wind box 111 through the heating pipe 104. A connection cylinder 112 fixed concentrically to the disk member 110 is accommodated in the inside of the wind box 111 on the lower surface of the disk member 110. The connecting cylinder 112 communicates with the air supply tower 103 through a through hole 110 a formed at the center of the disk member 110. A plurality of communication openings 112 a, 112 a,... Are formed on the side surface of the connection cylinder 112. The heated gas in the wind box 111 flows into the connection tube 112 through the communication openings 112a, 112a,... And is supplied to the air supply tower 103 through the connection tube 112 and the through hole 110a of the disk member 110. Is formed.

  A rotating shaft 113 connected to a motor (not shown) is fixed to the lower end surface of the connecting cylinder 112. A rotating force is input to the rotating shaft 113 by the motor, and the disk member 110 fixed to the connecting cylinder 112 is connected to the rotating cylinder 113. The air supply tower 103 and the rotary blade 107 fixed to the disk member 110 are rotationally driven.

  Below the bottom of the storage / drying chamber 121, a screw conveyor 108 is provided as a discharge unit that is disposed below the disk member 110 and extends in the tangential direction of a circle drawn by the periphery of the disk member 110 in plan view. The screw conveyor 108 communicates with a part of the peripheral edge of the bottom of the storage / drying chamber 121. Through this communication portion, the chip T is sent from the storage / drying chamber 121 to the screw conveyor 108 by the action of the rotary blade 107 that rotates together with the disk member 110.

  A discharge port 181 for the chip T is provided on the lower surface of one end of the screw conveyor 108. The screw conveyor 108 has a rotating shaft 182 that receives a rotational force from a motor (not shown), and a spiral blade 183 fixed around the rotating shaft 182.

  The discharge port 181 of the screw conveyor 108 is connected to a fuel conveyor of a boiler (not shown), and is configured to supply the chip T discharged from the discharge port 181 to the boiler burner through the fuel conveyor. A part of the combustion gas of the boiler burner is formed to be supplied to the heating pipe 104 as shown by an arrow G through a gas pipe (not shown).

  The operation of the rotary blade 107 serving as a discharge unit that discharges the chips T from the storage drying chamber 121 to the screw conveyor 108 is controlled by a control unit (not shown). The control unit controls the operation of the rotating blade 107 based on the detection signal from the moisture sensor S1 installed in the storage / drying chamber 121, that is, the rotation of the disk member 110 via the rotating shaft 113 and the connecting cylinder 112. Is formed. Thus, the control unit functions as a drying control unit. The moisture sensor S <b> 1 is provided on the inner wall surface of the storage / drying chamber 21.

  The chip drying apparatus 101 according to the second embodiment operates as follows.

  First, the chip T is supplied to the storage / drying chamber 121 through the chip supply pipe 122, and the combustion gas as the heating gas is supplied from the boiler to the heating pipe 104.

  The chips T discharged from the chip supply pipe 122 are distributed around the side network 131 by the upper end network 132 of the air supply tower 103, and the side network 131 of the air supply tower 103 and the storage drying chamber 121. It is accommodated between the inner side surface 121a.

  The heated gas supplied to the heating pipe 104 is guided to the air supply tower 103 through the wind box 111, the connecting cylinder 112, and the through hole 110 a of the disk member 110, and the chip T around the air supply tower 103 through the side network 131. To be supplied. With this heated gas, the chip T is heated and water is evaporated. The heated gas that has heated the chip T includes moisture evaporated from the chip T and is discharged to the outside from the chip insertion port 102a.

  When the chip T is dried and the moisture sensor S1 detects that the moisture content of the chip T is below a predetermined reference value, the rotating shaft 113 is rotated by the control of the control unit, and the disk member 110 and the air supply tower 103 are rotated. The rotary blade 107 is driven to rotate, and the chips in the storage / drying chamber 121 are discharged to the screw conveyor 108 by the rotary blade 107. Moreover, the screw conveyor 108 is started by control of a control part, the chip | tip T is conveyed, and the chip | tip T is delivered from the discharge port 181 to the fuel conveyor of the boiler which is not shown in figure.

  When the chip T in the storage / drying chamber 121 is discharged and the chip T is newly discharged from the chip supply pipe 122 and the water content of the chip T exceeds the reference value, the rotation speed of the rotary blade 107 is reduced by the control of the control unit. Or it is stopped. As a result, the residence time of the chip T in the storage / drying chamber 121 becomes longer, or the chip T stays in the storage / drying chamber 121 and is sufficiently heated by the heated gas to promote drying. When the tip T is dried and the moisture sensor S1 detects that the moisture content is below a predetermined reference value, the rotational speed of the rotary blade 107 is increased or stopped by the control of the control unit. Is activated, and the chip T is discharged from the storage / drying chamber 121 to the screw conveyor 108. Thus, the operation of the rotary blade 107 is controlled by the control unit according to the water content of the chip T in the storage / drying chamber 121. Therefore, even if chips T having different moisture contents are supplied, such as chips formed from building waste materials having a low water content or thinned wood materials having a high water content, the water content of the chips T will be adjusted. Thus, the drying time can be adjusted, and chips having a predetermined water content can be obtained stably.

  In the chip drying apparatus 101 according to the present embodiment, the air supply tower 103 is in a period from when the chips introduced into the storage / drying chamber 121 through the chip supply pipe 122 through the inlet 102a are discharged by the rotary blades 107 of the storage / drying chamber 121. Since it dries with the heated gas blown out from, it can reduce in size rather than the rotary kiln provided with the rotary furnace. Therefore, even if this chip drying apparatus 101 comprises a boiler apparatus combining with the boiler which uses the chip | tip T as a fuel, a boiler apparatus can be reduced in size effectively.

  Further, since the chip drying apparatus 101 dries the chip T in the storage drying chamber 121 with the heated gas blown out from the air supply tower 103, the chip T stays in the storage drying chamber 121 by adjusting the staying time of the chip T in the storage drying chamber 121. The drying ability of T can be easily adjusted. Therefore, since the drying capacity can be easily adjusted according to the moisture content of the chip T, plants with a predetermined moisture content can be prepared using materials with different moisture content such as building waste materials with low moisture content and thinned wood with high moisture content. Biomass chips can be manufactured stably and easily. Note that the drying capacity of the chip drying apparatus 101 may be adjusted by adjusting the temperature and flow rate of the heated gas from the air supply tower 103.

  Further, in the chip drying apparatus 101, since the housing / drying chamber 121 is formed such that the lower cross-sectional area is larger than the upper cross-sectional area, the internal chip T can be smoothly moved downward. Therefore, although the wood chip is an irregular shape with many corners and the bridge is relatively easily generated, the generation of the bridge can be prevented by the storage drying chamber 121, so that the chip T can be smoothly dried and discharged. Can do.

  Further, since the disk member 110 on which the rotary blades 107 are installed is disposed at the bottom of the frustoconical storage drying chamber 121, the relatively wide space at the bottom having the circular shape of the storage drying chamber 121 is effectively used, The rotary blades 107 can be arranged without increasing the diameter of the rotor. Therefore, the chip drying apparatus 101 can adjust the discharge amount of the chip T effectively while being vertically long and small, that is, can effectively adjust the staying time of the chip T in the accommodation drying chamber, thereby drying the chip. The degree can be adjusted flexibly.

  In each of the above embodiments, the moisture sensor S1 for detecting the moisture content of the chip T is provided, but the moisture sensor S1 may be omitted.

  Further, each of the chip drying apparatuses 1 and 101 is installed in combination with a boiler that uses dried wood chips as fuel, but may be installed in an apparatus other than the boiler, for example, installed in a wood chip manufacturing apparatus. May be.

  Moreover, although each said chip drying apparatus 1 and 101 utilized the combustion gas of the boiler as heating gas, you may use other heating gas, such as the air heated with the heater.

  Moreover, each said chip drying apparatus 1,101 is not restricted to a wood chip | tip, It can apply to the drying of the chip | tip of various plant biomass, such as a grain husk, a rice husk, and a bamboo.

DESCRIPTION OF SYMBOLS 1 Chip drying apparatus 2 Casing 2a Chip inlet 3 Supply gas 4 Heating piping 6 Current plate 7 Rotating blade 21 Accommodating drying chamber 23 Pre-transport chamber 31 Supply gas network S1 Moisture sensor S2 Chip amount sensor

Claims (9)

A chip drying device for drying vegetable chips,
A storage drying chamber in which the lower cross-sectional area is larger than the upper cross-sectional area;
A chip insertion port provided at the top of the storage drying chamber;
Arranged in the storage / drying chamber, the upper cross-sectional area is formed smaller than the lower cross-sectional area, and the heated gas supplied to the inside at the lower part is guided upward, and from the outlet provided on the surface into the storage / drying chamber. A heated gas distributor that blows out;
A discharge section for discharging chips from the storage drying chamber;
A chip drying apparatus comprising: a transport unit that transports the chips discharged by the discharge unit. The chip drying apparatus according to claim 1,
The storage drying chamber is formed in a substantially box-like shape in which the two inner side surfaces facing each other incline in opposite directions and spread outwardly,
The heated gas distribution part is disposed substantially parallel to the two inner side surfaces of the storage drying chamber and has two nets inclined in opposite directions on the surface,
The discharge part is disposed in the vicinity of the lower end edges of the two mesh bodies of the heated gas distribution part, and is formed by two rotating blades that are driven to rotate around a rotation axis parallel to the lower end edges of the mesh bodies,
The said drying part has the screw conveyor arrange | positioned substantially parallel to a rotary blade below the two rotary blades of the said discharge part, The chip drying apparatus characterized by the above-mentioned. The chip drying apparatus according to claim 2,
The heated gas distribution unit includes an air supply unit that supplies heated gas between the mesh bodies, and a rectifying plate that distributes the heated gas supplied from the air supply unit in the width direction of the network body. Chip drying device. The chip drying apparatus according to claim 2,
The screw dryer of the said conveyance part is formed in the unequal pitch whose pitch is so large that a screw progresses in the carrying-out direction of a chip | tip, The chip drying apparatus characterized by the above-mentioned. The chip drying apparatus according to claim 1,
The storage drying chamber is formed in a truncated cone shape,
The heated gas distribution section has a frustoconical side-surface-shaped net disposed coaxially with the frustoconical storage drying chamber on the surface,
The discharge part is formed by rotating blades that are arranged radially at the bottom of the frustoconical storage drying chamber and are driven to rotate around the central axis of the circular bottom surface of the storage drying chamber,
The chip drying apparatus, wherein the conveying unit includes a screw conveyor that is disposed below the rotary blades of the discharge unit and extends in a tangential direction of an arc drawn by a tip of the rotary blades in plan view. The chip drying apparatus according to claim 5,
A disk member is provided at the bottom of the storage drying chamber,
The heated gas distribution part and the rotating blade are fixed to the surface of the disk member,
A chip drying apparatus, wherein the heated gas distribution part and the rotary blade are formed to rotate about a concentric axis as the disk member is rotationally driven. The chip drying apparatus according to claim 1,
A front chamber for temporarily storing the chips discharged from the discharge unit before being transferred by the transfer unit;
A chip amount sensor for detecting the amount of chips in the pre-transport chamber;
A chip drying apparatus comprising: a discharge control unit that controls an operation of the discharge unit based on a detection signal of the chip amount sensor. The chip drying apparatus according to claim 1,
A moisture sensor for detecting the moisture content of the chip in the storage drying chamber;
A chip drying apparatus comprising: a drying control unit that controls the operation of the discharging unit based on a detection signal of the moisture sensor. The chip drying apparatus according to claim 1,
2. The chip drying apparatus according to claim 1, wherein the heated gas is a burner combustion gas using the chip conveyed from the conveying unit as fuel.

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