CN101779757A - Box type multi-stage dryer with microwave drying systems and drying method applying same - Google Patents

Abstract

The invention discloses a box type multi-stage dryer with microwave drying systems and a drying method applying the same. The dryer comprises a box, a separation system, a multi-stage drying system, transfer systems, a sealing system, a feeding system, a discharging system and the microwave drying systems. The separation system is positioned in the box and comprises a separation wall and a group of separation layers to separate the box into a group of drying chambers. Transfer belts in the transfer systems comprise a group of openings distributed equidistantly and sealing structures positioned at both sides of the openings. The sealing system comprises a group of sealing gates and a group of sealing auxiliary structures. The microwave drying systems are a group of microwave devices arranged on the separation wall and are used for uniformly drying the materials in the drying chambers.

Description

A kind of box type multi-stage drying tower and furnace drying method thereof with microwave drying

Technical field

The present invention relates to a kind of box type multi-stage drying tower, particularly a kind of box type multi-stage drying tower with microwave drying.

The invention still further relates to a kind of employing and have the furnace drying method that the box type multi-stage drying tower of microwave drying is dried.

Background technology

In the reconstituted rice process, need dry cooling to the reconstituted rice particle after the extruding cutting.Yet the reconstituted rice particle water content after the extruding cutting is higher, temperature is higher, starch component wherein is under the big condition of temperature high humility, the gelatinization effect can take place, and makes the outer surface of reconstituted rice particle have higher viscosity, this also caused between the reconstituted rice particle to be stained with sticking degree bigger.

For the oven dry of solid particle material, often adopt tower baker, cylinder baker etc., under the convection current or following current effect of hot-air, the moisture of solid particle material is taken away, thereby with its oven dry.Yet because reconstituted rice particle outer surface has viscosity higher,, will very easily be stained with the group of sticking between the reconstituted rice particle, block drying tower in case adopt baroque tower drying tower to carry out large batch of oven dry.Be stained with coherent particle simultaneously and also can bring the uneven situation of oven dry.

Because the reconstituted rice water content is higher, in drying course, as drying fast, when reaching the water content requirement, the outer surface of reconstituted rice particle produces the crackle of be full of cracks through regular meeting.This is because when adopting hot-air seasoning in the drying course, hot-air is taken away the water of particle surface rapidly, and that the water of granule interior is not easy is volatilized, thereby make particle surface different with the evaporation rate of the water of inside, when the water content of granule interior reached requirement, particle surface was but because dehydration too much produces be full of cracks.Another causes the reason of above-mentioned situation to be, the process of oven dry is fierce too rapidly, there is not time enough to be diffused into particle surface by the water of granule interior, remedy surperficial different and water content difference that bring with the internal water evaporation rate, make granule interior and the surface the water content balance, avoid surface checking.

Simultaneously in the reconstituted rice drying course, because surface and inner water content inequality, even if the particle surface after the oven dry is be full of cracks not, yet after placing a period of time, still can chap, and the situation of this water content inequality also caused boiling in the process in reconstituted rice, and the reconstituted rice particle is very easily damaged, causes nutriment that reconstituted rice adds etc. to run off along with water.

Yet existing drying tower and method can't solve that reconstituted rice is intergranular is stained with sticking situation, and it is uneven and produce the situation of be full of cracks also can't to solve the volatilization of particle surface and internal moisture.

Chinese patent application 200510017417.X discloses a kind of furnace drying method and oven dry unit thereof of high moisture material.This method is placed on high moisture material flash baking in the swirling eddy dryer earlier then and continues oven dry in the fluid bed dryer with the lower particle of water content that obtains, obtain product.Though this method resolved into for two steps with drying course, avoid carrying out the too fast situation of hyperthermia drying dehydration always, yet how to avoid being stained with stickingly between the material particles, how to avoid high viscosity particulates plug drying tower, how above-mentioned particle is evenly dried, this patent application still just fails to solve.

Chinese patent application 200710023923.9,200510043078.2 and 200610160006.0 discloses a kind of microwave vacuum drying plant.This equipment adopts microwave and vacuum equipment that materials inside is dried.Because microwave drying, the material of being dried can be dried internally, and inner with surperficial water evaporation rate is identical, thereby can avoid the situation of dehydration inequality.Be stained with stickingly yet this equipment can't solve between granule materials, and can't dry for large batch of material, the speed of oven dry is slow, cost is higher.

PCT International Application PCT DE2006/000639 discloses a kind of drying tower with demarcation strip, and korean patent application KR10-2006-0095243 also discloses a kind of air flow dryer with compartment of some supporting plates formation simultaneously.Though above-mentioned patent application is separated into some parts by elements such as demarcation strips with material, dry then, can less particle and particle between the situation of oven dry inequality, yet above-mentioned patent application can't solve the problem for its inside and outside dehydration inequality of particle, also can't avoid being stained with between particle sticking.

Chinese patent application 200710133825.0 discloses a kind of rotary drying machine.This dryer has the X-shaped lifting blade, material can be thrown repeatedly to fall, and makes the holdup time of material in dryer increase and makes material disperse, thereby allow evenly oven dry between the material.Yet this patent application still can't solve the situation of a granule interior and surperficial dehydration inequality.

Chinese patent application 200610062685.8 discloses a kind of dryer.This dryer is a kind of oven dry casing, adopts the heating evaporation oven dry early stage, and the later stage is adopted the frequency electromagnetic waves heating, so that quick integral heating from inside to outside, and not damaged oven dry object.Yet this device can't be avoided intergranular and be stained with stickingly, and adopts frequency electromagnetic waves to heat, and can't carry out the oven dry of a large amount of materials.

Chinese patent application 200410068779.7 based on Japanese patent application JP1919/2004 and JP53002/2004 discloses a kind of drying tower.The purpose of this application is to provide a kind of drying tower that adheres to and can effectively dry granule mutually that prevents.This device is imported the pipeline that many inside have feeding screw with granule, carries out heating, drying in pipeline, and utilizes the stirring action of feeding screw at pipe interior, disperses the granule that adheres to mutually.Yet for the big granule of surface viscosity, the pipeline of this invention is blocked easily.This device construction complexity can't be carried out the oven dry of material in enormous quantities simultaneously, and this device also can't be avoided the situation of particle surface and inner dehydration inequality simultaneously.

PCT International Application PCT/JP2003/013360 discloses a kind of drying tower of powder and granular material.This device at the built-in electric heater of central authorities, and have a plurality of partition walls be radial outstanding heat conducting and radiating sheet be housed in inside hopper.In the compartment that powder body material to be dried is distributed in and a plurality of partition wall constitutes, by the hot air dries of convection current.Though powder body material is separated and is some groups, can promote the even oven dry of material, yet still can't avoid bonding and the inner and surperficial even oven dry of material between material particles.

Summary of the invention

The invention discloses a kind of box type multi-stage drying tower, comprise casing, separating system, multistage drying system, transfer system, sealing system, feed system, discharge system and microwave drying system.

Described casing is the cube structure of a hollow, further comprises top layer and one group of side door.

Described separating system is positioned at box house, comprises a dividing wall and a component interlayer.Described dividing wall and each separate layer are separated into some drying chambers with casing, to form described drying system.

Described dividing wall is the hollow wall structure that vertically distributes, and is positioned on the center line of casing, and casing is divided into left side casing and right side casing.The top layer of casing is passed on the top of described dividing wall, is exposed to the outside of casing.Be distributed with one group of pore on the left side body of wall of described dividing wall and the right side body of wall.Described pore passes left side body of wall and right side body of wall and each drying chamber inside respectively and is interconnected, enter each drying chamber inside to allow the dividing wall gas inside to pass the outside unidirectional discharge of body of wall, and allow each drying chamber gas inside to be taken away by pore by pore.Have one group of air admission hole and one group of steam vent on the top of described dividing wall, described air admission hole and steam vent are communicated with the inside of dividing wall hollow, are used for taking gas away to its inner input gas with from its inside.

Described separate layer is the planar structure of horizontal distribution, and the position vertically is divided into sandwich construction with casing.Described separate layer is connected on the dividing wall, and support on it transfer system.

Described multistage drying system is positioned at box house, has one group of drying chamber that is surrounded by casing, separating system and sealing system.

Described transfer system comprises that one group is placed on each separate layer and the surface has the conveyer structure of the arc groove that is used to prevent that material from sliding.Described conveyer structure further comprises conveyer belt and one group of transmission shaft.

Described transmission shaft is used for the conveyer belt on it is sent to the rear side that casing is connected with discharge system from the front side that casing is connected with feed system.Described conveyer belt comprises one group of opening that equidistantly distributes and the hermetically-sealed construction that is positioned at each opening both sides.The inner surface that described conveyer belt and transmission shaft are in contact with one another is provided with gear, and the gear on this gear and transmission shaft surface is meshing with each other, to realize synchronous driving.

Described conveyer belt outer surface has the arc groove of continuous distributed, slides to prevent the material on it.Described arc groove is that its radian is 50 °～130 ° by the arc concave configuration that most advanced and sophisticated projection surrounded around it, is line style at the conveyer belt outer surface along direction of transfer and distributes or matrix distribution.Described sealing system comprises one group of sealed gate being positioned at box house, be positioned at one group of lifting motor of each sealed gate inside and one group of elevating lever and around one group around each sealed gate sealing supplementary structure.

Described sealed gate is a kind of movable gate, comprises top gate and bottom gate.Described top gate and bottom gate have adaptive inclined-plane mutually, are used to carry out the seal closure of gatehouse, and the oblique angle on described inclined-plane is 24 °～66 °.

Described top gate comprises the inside of bottom, hollow and has the top of opening, and passes through on the separate layer of top portion fixed thereon.The inside of described top gate has the lifting motor and the elevating lever that is connected thereon that is installed on the bottom.Described elevating lever connects and supports and is positioned at the respective lower gate of last layer, and drives this bottom gate and move up and down.

Described bottom gate is positioned at the respective upper gate inside of one deck down, can pass the opening at top and the respective openings on the conveyer belt moves up and down, when rising, pass this opening and do the inclined-plane seal closure, when descending, pass the inside of the respective upper gate hollow of one deck under this opening indentation with the respective upper gate of layer.

Described sealing supplementary structure is a kind of closed-in construction, is in the same perpendicular with corresponding sealed gate, is used for sealed gate is connected with on every side body structure, separate layer structure, driving-belt structure, dividing wall sealing structure.The described supplementary structure side adjacent with dividing wall that respectively seal extended and is inserted into dividing wall inside, and dividing wall inside is separated into the interior zone that one group of inside is separate, not exchange information, an all corresponding drying chamber and the drying chamber that is positioned at its right side that is positioned at its left side of each interior zone, and the respective tops of each interior zone has an air admission hole and a steam vent.

Described feed system comprises one group and is positioned at the casing front side, and the charging aperture that is interconnected with each drying chamber of casing front side.Described charging aperture is connected on the left upper portion gate of front side corresponding with it drying chamber.The charging port of described charging aperture is positioned at conveyer belt top, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it.

Described discharge system comprises one group and is positioned at the casing rear side, and the discharging opening that is interconnected with each drying chamber of casing rear side.Described discharging opening is connected on the right upper portion gate of rear side drying chamber corresponding with it.The discharging port of described discharging opening is positioned at the conveyer belt bottom, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it.

Described microwave drying system comprises the left side body of wall that is positioned at dividing wall and one group of microwave device on the body of wall of right side.Described each microwave device comprises microwave generator and microwave waveguide device, is used for generating and the conduction microwave, to dry the material in each drying chamber.Be provided with 1～4 microwave device in described each drying chamber.Each drying chamber of described multistage drying system is surrounded by casing, separating system and sealing system.The left and right sides of described drying chamber is that two sealed gates and two sealing supplementary structure, rear side are that dividing wall, front side are that side door, the end face of casing is that separate layer, bottom surface are conveyer belt, two transmission shafts and 4 adjacent openings.

The gap width of described opening equates that with the thickness of sealed gate the gap length of opening equates with its width, so that sealed gate passes opening and driving fit just.

The outside width of described sealing supplementary structure and conveyer belt width are equal, inboard width equates with the sealed gate width, height equates with the vertical spacing of separate layer and conveyer belt, be closed into a hermetically-sealed construction so that the sealing supplementary structure can connect dividing wall, demarcation strip, sealed gate, conveyer belt and opening thereof.

The spacing that is positioned at two adjacent apertures on the same horizontal plane equates with the spacing of two sealed gates.Two other opening is overlapping with aforementioned two opening in the vertical directions respectively, so that sealed gate can pass two openings on the vertical direction simultaneously, thereby is retracted to the gate inside, top of lower floor.

Be provided with 2～6 separate layers, 4～10 sealed gates in the described casing, thereby make multistage drying system have 2 * 2 * 3～2 * 6 * 9 drying chambers, and 2 * 2～2 * 6 charging apertures and 2 * 2～2 * 6 discharging openings.

The present invention discloses a kind of method that adopts above-mentioned box type multi-stage drying tower to dry, comprise following steps:

Step 31:, material particles to be dried is input on the conveyer belt with the corresponding drying chamber of this charging aperture by each charging aperture of feed system.

Step 32: conveyer belt under the drive of transmission shaft, the side shifting backward from the front side of casing, in this process, material particles covers full conveyer belt gradually.

Step 33: the gear of conveyer belt and transmission shaft is meshing with each other, and moves to assigned position so that transmission shaft drives conveyer belt synchronously, and promptly each opening on the conveyer belt and corresponding sealed gate in the vertical direction are overlapping.

Step 34: the lifting motor of gate inside, following one deck top drive elevating lever with and go up the bottom gate that connects and rise, eject from this time one deck top gate is inner, pass on the driving-belt corresponding opening, rise and carry out the inclined-plane seal closure with respective upper gate with one deck.

Step 35: after treating each sealed gate closure, oven dry with uniform temperature humidity enters into dividing wall inside with gas from each air admission hole on dividing wall top, discharge by each pore on left side body of wall and the right side body of wall subsequently, so that gassy in each airtight relatively independent drying chamber, thereby oven dry material particles.

After drying time finishes, by each steam vent on dividing wall top, utilize the above-mentioned pore on the body of wall again, each drying chamber gas inside is taken away.

Because each drying chamber is relatively independent and airtight, and described sealing supplementary structure to be a kind of closed-in construction be separated into the interior zone that one group of inside is separate, not exchange information with dividing wall inside, and scope that should the zone is identical with the drying chamber scope, so air admission hole and steam vent by each interior zone top can carry out oven dry in various degree to the inner gas that injects different temperatures humidity of each drying chamber.

Step 36: in above-mentioned drying course, energising starts the microwave generator of each microwave drying system, produces microwave, and transmits by the microwave waveguide device, thereby to the drying materials on the conveyer belt in the drying chamber.

Step 37: after the end of waiting to bleed, the lifting motor of gate inside, following one deck top drive elevating lever with and go up the bottom gate that connects and descend, be separated from each other with respective upper gate with one deck, pass on the driving-belt corresponding opening, descend and be retracted to the corresponding hollow inside of one deck top gate down.

Step 38: this moment, each sealed gate was opened, and conveyer belt continues to move under the drive of transmission shaft, material particles is sent in the next drying chamber dries.

Step 39: will dry good material particles and output to each discharging opening with the corresponding discharge system of this conveyer belt by conveyer belt.

Box type multi-stage drying tower of the present invention is separated segmentation of structures such as wall, demarcation strip and becomes the left and right sides, the drying chamber of multilayer up and down, and along the direction of conveyer belt, the sealed again gate of above-mentioned drying chamber further is separated into the drying chamber of some openable relatively independent sealings.The characteristics of this drying chamber are that the sealed gate of its both sides can be opened or close as required, thereby form air-tight state, and in this confined space, material grains to be dried can be by the gas drying of the discharge of the pore from dividing wall.Furthermore, because extending, the sealing supplementary structure inserts dividing wall, make dividing wall inside be separated into some relatively independent structures, so for a drying chamber, the gas passage of the dividing wall that it is corresponding is independently, promptly this section dividing wall can be independently the gas of air admission hole input specified temp humidity by the top enter drying chamber inside.That is to say that along on the conveyer belt direction, gas and drying environment in each drying chamber can be different, thereby for the same batch materials particle along the conveyer belt transmission, dry step by step, promptly pass the drying chamber with different temperatures humidity successively.In general, the difference of this temperature humidity refers to, temperature humidity changes with certain gradient, thereby make material particles can be slowly gradually quilt dry, thereby the fast inner dehydration of the surperficial dehydration of avoiding the excessive oven dry of temperature humidity difference to be caused slowly and phenomenon and problem such as the surface checking that brings thus, oven dry be insufficient.For each drying chamber of left and right sides in the same perpendicular and levels, its inner drying condition is equal to.So utilize device of the present invention can carry out multiple batches of oven dry simultaneously, and obtain the identical material particles of oven dry degree.Another advantage of the present invention is, first material is sent to each drying chamber oven dry along conveyer belt when, second batch materials also is transmitted band subsequently and delivers to the drying chamber oven dry adjacent with first material, that is to say, this multistage oven dry of the present invention continues to feed intake and continues output, can continuously dry material particles.Simultaneously because device of the present invention has a plurality of conveyer belts and drying chamber, and the inventory of oven dry is very easily controlled, and, in device of the present invention, can be avoided because of inventories such as inventory is excessive or too small change the influence to drying effect that is brought.

What the temperature humidity of each drying chamber of the present invention can oppose relatively regulates and control, and can be widely applicable for different oven dry flow processs and oven dry demand.Gas owing to each grade oven dry is recycled respectively simultaneously, and because the temperature difference psychrometric difference of each grade oven dry that classification brought is all less, so to low many of the required energy consumption of recycling of the using back gas gas bigger, so the present invention can energy savings than the temperature difference psychrometric difference.

Description of drawings

Fig. 1 is the overall structure perspective view of box type multi-stage drying tower of the present invention.

Fig. 2 a is the front view of box type multi-stage drying tower of the present invention.

Fig. 2 b is the vertical view of box type multi-stage drying tower of the present invention.

Fig. 2 c is the structural representation of box type multi-stage drying tower of the present invention.

Fig. 2 d is the structural representation of box type multi-stage drying tower of the present invention.

Fig. 3 a is the plan structure sketch of conveyer belt of the present invention.

Fig. 3 b is the side view of conveyer belt of the present invention.

Fig. 3 c is the local detail view of conveyer belt of the present invention.

Fig. 3 d is the plan structure schematic diagram of conveyer belt of the present invention.

Fig. 4 is the structure and the operation principle schematic diagram of sealing system of the present invention.

Fig. 5 a is the structural representation of the closure state of conveyer system of the present invention and sealing system.

Fig. 5 b is the structural representation of the open mode of conveyer system of the present invention and sealing system.

Fig. 6 is the structural representation of microwave drying of the present invention system.

Fig. 7 is the local detail view of drying chamber of the present invention.

The specific embodiment

According to claim of the present invention and the disclosed content of summary of the invention, technical scheme of the present invention is specific as follows described:

Embodiment one:

According to Fig. 1:

A kind of box type multi-stage drying tower comprises casing 301, separating system 302, multistage drying system 303, transfer system 304, sealing system 305, feed system 306, discharge system 307 and microwave drying system 308.

According to Fig. 2 a:

Described casing 301 is cube structures of a hollow, further comprises top layer 3011 and one group of side door 3012.

According to Fig. 2 c, 2d:

Described separating system 302 is positioned at casing 301 inside, comprises a dividing wall 3021 and a component interlayer 3022.Described dividing wall 3021 and each separate layer 3022 are separated into some drying chambers 3030 with casing 301, to form described drying system 303.

According to Fig. 2 c:

Described separate layer 3022 is planar structures of horizontal distribution, and the position vertically is divided into sandwich construction with casing 301.Described separate layer 3022 is connected on the dividing wall 3021, and support on it transfer system 304.

According to Fig. 2 d:

Described dividing wall 3021 is the hollow wall structures that vertically distribute, and is positioned on the center line of casing 301, and casing 301 is divided into left side casing 3013 and right side casing 3014.The top layer 3011 of casing 301 is passed on the top 3023 of described dividing wall 3021, is exposed to the outside of casing 301.Be distributed with one group of pore 3020 on the left side body of wall 3024 of described dividing wall 3021 and the right side body of wall 3025.Described pore 3020 passes left side body of wall 3024 respectively and right side body of wall 3025 is interconnected with each drying chamber 3030 inside, enter each drying chamber 3030 inside to allow dividing wall 3021 gas inside to pass the outside unidirectional discharge of body of wall, and allow each drying chamber 3030 gas inside to be taken away by pore 3020 by pore 3020.

According to Fig. 2 b:

Have one group of air admission hole 30231 and one group of steam vent 30232 on the top 3023 of described dividing wall 3021, described air admission hole 30231 and steam vent 30232 are communicated with the inside of dividing wall 3021 hollows, are used for taking gas away to its inner input gas with from its inside.

According to Fig. 1 and Fig. 2 a, 2b, 2c, 2d:

Described multistage drying system 303 is positioned at casing 301 inside, has one group of drying chamber 3030 that is surrounded by casing 301, separating system 302 and sealing system 305.More than each figure showed one group of drying chamber 3030 of described box type multi-stage drying tower clearly.

According to Fig. 3 a, 3b, 3c, 3d:

Described transfer system 304 comprise one group be placed on each separate layer 3022 and the surface have be used to prevent arc groove that material slides conveyer structure 3040.Described conveyer structure 3040 further comprises conveyer belt 3041 and one group of transmission shaft 3042.

Described transmission shaft 3042 is used for the conveyer belt on it 3041 is sent to the rear side that casing 301 is connected with discharge system 307 from the front side that casing 301 is connected with feed system 306.Described conveyer belt 3041 comprises one group of opening 3043 that equidistantly distributes and the hermetically-sealed construction 3044 that is positioned at each opening 3043 both sides.Described conveyer belt 3041 is provided with gear with the inner surface that transmission shaft is in contact with one another, and the gear on this gear and transmission shaft 3042 surfaces is meshing with each other, to realize synchronous driving.

Described conveyer belt 3041 outer surfaces have the arc groove 3046 of continuous distributed, slide to prevent the material on it.Described arc groove 3046 is the arc concave configuration that surrounded by the most advanced and sophisticated projection 3045 around it, and its radian c2 is 50 °～130 °, is line style at conveyer belt 3041 outer surfaces along direction of transfer and distributes or matrix distribution.Among Fig. 3 d, left hand view has showed that arc groove is the partial top view of the conveyer belt of matrix distribution, and right part of flg has showed that arc groove is the partial top view of the conveyer belt of line style distribution.

According to Fig. 4 and Fig. 5 a, 5b:

Described sealing system 305 comprises one group of sealed gate 3050 being positioned at casing 301 inside, be positioned at one group of lifting motor 3053 of each sealed gate 3050 inside and one group of elevating lever 3054 and around one group of sealing supplementary structure 3055 around each sealed gate 3050.

Described sealed gate 3050 is a kind of movable gates, comprises top gate 3051 and bottom gate 3052.Described top gate 3051 and bottom gate 3052 have adaptive inclined-plane mutually, are used to carry out the seal closure of gatehouse, and the oblique angle c1 on described inclined-plane is 24 °～66 °.

Described top gate 3051 comprises the inside of bottom 30510, hollow and has the top of opening, and passes through on the separate layer 3022 of top portion fixed thereon.The inside of described top gate 3051 has the lifting motor 3053 and the elevating lever 3054 that is connected thereon that is installed on the bottom 30510.Described elevating lever 3054 connects and supports and is positioned at the respective lower gate 3052 of last layer, and drives this bottom gate 3052 and move up and down.

Described bottom gate 3052 is positioned at respective upper gate 3051 inside of one deck down, can pass the opening at top and the respective openings 3043 on the conveyer belt 3041 moves up and down, when rising, pass this opening 3043 and do the inclined-plane seal closure, when descending, pass the inside of respective upper gate 3051 hollows of one deck under these opening 3043 indentations with the respective upper gate 3051 of layer.

The left side of Fig. 4 is the cross section view of described sealing system, and the right is the front view of described sealing system.Fig. 4 has not only showed the sealing system that is in open mode, has also showed the sealing system that is in closure state.Fig. 5 a, 5b have showed the transfer system that is under closure and the open mode and the duty of sealing system respectively.In Fig. 5 a, the bottom gate rises, closed each the relatively independent drying chamber 3 that forms of sealing system, and in Fig. 5 b, the bottom gate descends, sealing system is opened, each drying chamber of same horizontal plane is interconnected, be convenient to conveyer belt with and on material transport forward by each gate successively.

According to Fig. 4 and Fig. 7:

Described sealing supplementary structure 3055 is a kind of closed-in constructions, is in the same perpendicular with corresponding sealed gate, is used for sealed gate is connected with on every side body structure, separate layer structure, driving-belt structure, dividing wall sealing structure.Described supplementary structure 3055 and the dividing wall 3021 adjacent sides that respectively seal are extended and are inserted into dividing wall 3021 inside, and dividing wall 3021 inside are separated into the interior zone that one group of inside is separate, not exchange information, an all corresponding drying chamber 3030 and the drying chamber 3030 that is positioned at its right side that is positioned at its left side of each interior zone, and the respective tops of each interior zone has an air admission hole 30231 and a steam vent 30232.

According to Fig. 1, Fig. 2 b and Fig. 5 a, 5b:

Described feed system 306 comprises one group and is positioned at casing 301 front sides, and the charging aperture 3060 that is interconnected with each drying chamber of casing front side.Described charging aperture 3060 is connected on the left upper portion gate 3051 of front side corresponding with it drying chamber.The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it.

Described discharge system 307 comprises one group and is positioned at casing 301 rear sides, and the discharging opening 3070 that is interconnected with each drying chamber of casing rear side.Described discharging opening 3070 is connected on the right upper portion gate 3051 of rear side drying chamber corresponding with it.The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it.

According to Fig. 6 and Fig. 7:

Described microwave drying system 308 comprises the left side body of wall 3024 that is positioned at dividing wall 3021 and one group of microwave device 3080 on the right side body of wall 3025.Described each microwave device 3080 comprises microwave generator and microwave waveguide device, is used for generating and the conduction microwave, to dry the material in each drying chamber.Be provided with 1～4 microwave device 3080 in described each drying chamber 3030.

According to Fig. 7:

Each drying chamber 3030 of described multistage drying system 303 is surrounded by casing 301, separating system 302 and sealing system 305.The left and right sides of described drying chamber 3030 is that two sealed gates 3050 and two sealing supplementary structure 3055, rear side are that dividing wall 3021, front side are that side door 3012, the end face of casing 301 is that separate layer 3022, bottom surface are conveyer belt 3041, two transmission shafts 3042 and 4 adjacent openings 3043.

The gap width of described opening 3043 equates that with the thickness of sealed gate 3050 gap length of opening equates with its width, so that sealed gate passes opening 3043 and driving fit just.

The outside width of described sealing supplementary structure 3055 and conveyer belt 3041 width are equal, inboard width equates with sealed gate 3050 width, height equates with the vertical spacing of separate layer and conveyer belt, be closed into a hermetically-sealed construction so that the sealing supplementary structure can connect dividing wall 3021, demarcation strip 3022, sealed gate 3050, conveyer belt 3041 and opening thereof.

The spacing that is positioned at two adjacent apertures 3043 on the same horizontal plane equates with the spacing of two sealed gates 3050.Two other opening is overlapping with aforementioned two opening in the vertical directions respectively, so that sealed gate can pass two openings on the vertical direction simultaneously, thereby is retracted to the gate inside, top of lower floor.

From Fig. 1 and Fig. 2 c, 2d as can be known, the box type multi-stage drying tower has a plurality of drying chambers, two parts about these drying chambers are separated wall and are separated into, each part is separated into several layers by each separate layer again, and each layer is separated into some relatively independent drying chambers by each sealing system once more.Can be interconnected between each drying chamber with one deck, and material under driving, passes by driving-belt each drying chamber of this layer successively.Because the sealing supplementary structure is separated into some relatively independent interior zones with dividing wall, and each interior zone has oneself air inlet and exhaust outlet, so the temperature humidity of the gas of each interior zone turnover can independently be controlled.To sum up, the temperature humidity of one group of drying chamber vertically one group of drying chamber temperature humidity equal, along continuous straight runs is different.

According to Fig. 1 and Fig. 2 a, 2b, 2c, 2d:

Be provided with 3022,4～10 sealed gates 3050 of 2～6 separate layers in the described casing 301, thereby make multistage drying system 303 have 2 * 2 * 3～2 * 6 * 9 drying chambers 3030 (left and right sides number * number of plies * every layer of drying chamber number), and 2 * 2～2 * 6 charging apertures 3060 (left and right sides number * number of plies) and 2 * 2～2 * 6 discharging openings 3070 (left and right sides number * number of plies).

A kind of method that adopts above-mentioned box type multi-stage drying tower to dry comprises following steps: according to Fig. 1, Fig. 2 b and Fig. 5 a, 5b:

Step 31:, material particles to be dried is input on the conveyer belt 3041 with the corresponding drying chamber 3030 of this charging aperture by each charging aperture 3060 of feed system 306.

Step 32: conveyer belt 3041 under the drive of transmission shaft 3042, the side shifting backward from the front side of casing 301, in this process, material particles covers full conveyer belt 3041 gradually.

According to Fig. 3 a, 3b and Fig. 5 a, 5b:

Step 33: conveyer belt 3041 is meshing with each other with the gear of transmission shaft 3042, move to assigned position so that transmission shaft 3042 drives conveyer belt 3041 synchronously, promptly each opening 3043 on the conveyer belt 3041 is overlapping with corresponding sealed gate 3050 in the vertical directions.

According to Fig. 4 and Fig. 5 a:

Step 34: the lifting motor 3053 of gate 3051 inside, following one deck top drive elevating levers 3054 with and go up the bottom gate 3052 that connects and rise, from this time one deck top gate 3051 inner ejections, pass on the driving-belt 3041 corresponding opening 3043, rise and carry out the inclined-plane seal closure with respective upper gate 3051 with one deck.

According to Fig. 2 b, 2d and Fig. 7:

Step 35: after treating each sealed gate 3050 closures, oven dry with uniform temperature humidity enters into dividing wall 3021 inside with gas from each air admission hole 30231 on dividing wall 3021 tops, discharge by each pore 3020 on left side body of wall 3024 and the right side body of wall 3025 subsequently, so that gassy in each airtight relatively independent drying chamber 3030, thereby oven dry material particles.After drying time finishes, by each steam vent 30232 on dividing wall 3021 tops, utilize the above-mentioned pore 302 on the body of wall again, each drying chamber 3030 gas inside are taken away.

Because each drying chamber 3030 is relatively independent and airtight, and described sealing supplementary structure 3055 to be a kind of closed-in constructions be separated into the interior zone that one group of inside is separate, not exchange information with dividing wall 3021 inside, and scope that should the zone is identical with the drying chamber scope, so air admission hole and steam vent by each interior zone top can carry out oven dry in various degree to the inner gas that injects different temperatures humidity of each drying chamber.

According to Fig. 6

Step 36: in above-mentioned drying course, each microwave drying of energising startup is 308 microwave generator, produces microwave, and transmits by the microwave waveguide device, thereby to the drying materials on the conveyer belt 3051 in the drying chamber 3030.

According to Fig. 4 and Fig. 5 b:

Step 37: after the end of waiting to bleed, the lifting motor 3053 of gate 3051 inside, following one deck top drive elevating levers 3054 with and go up the bottom gate 3052 that connects and descend, be separated from each other with respective upper gate 3051 with one deck, pass on the driving-belt 3041 corresponding opening 3043, descend and be retracted to the corresponding hollow inside of one deck top gate 3051 down.

According to Fig. 3 a and Fig. 5 a, 5b:

Step 38: this moment, each sealed gate was opened, and conveyer belt 3041 continues to move under the drive of transmission shaft 3042, material particles is sent in the next drying chamber dries.

According to Fig. 1, Fig. 2 b and Fig. 5 a, 5b:

Step 39: will dry good material particles and output to each discharging opening with this conveyer belt 3041 corresponding discharge systems 307 by conveyer belt 3041.

Embodiment two:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 60 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 27 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 3mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 3mm with it.

3022,4 sealed gates 3050 of 2 separate layers are arranged in the described casing 301.2 sides, every side were each 2 layers, every layer each 3 about described box type multi-stage drying tower was total, amounted to 12 drying chambers.Be provided with 1 microwave device (3080) in described each drying chamber (3030).

Embodiment three:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 65 °.The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 30 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 5mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 5mm with it.

3022,5 sealed gates 3050 of 2 separate layers are arranged in the described casing 301.2 sides, every side were each 2 layers, every layer each 4 about described box type multi-stage drying tower was total, amounted to 16 drying chambers.Be provided with 1 microwave device (3080) in described each drying chamber (3030).

Embodiment four:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 70 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 36 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 7mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 7mm with it.

3022,6 sealed gates 3050 of 3 separate layers are arranged in the described casing 301.2 sides, every side were each 3 layers, every layer each 5 about described box type multi-stage drying tower was total, amounted to 30 drying chambers.Be provided with 2 microwave devices (3080) in described each drying chamber (3030).

Embodiment five:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 80 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 39 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 9mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 9mm with it.

3022,6 sealed gates 3050 of 3 separate layers are arranged in the described casing 301.2 sides, every side were each 3 layers, every layer each 5 about described box type multi-stage drying tower was total, amounted to 30 drying chambers.Be provided with 2 microwave devices (3080) in described each drying chamber (3030).

Embodiment six:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 90 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 42 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 11mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 11mm with it.

3022,7 sealed gates 3050 of 4 separate layers are arranged in the described casing 301.2 sides, every side were each 4 layers, every layer each 6 about described box type multi-stage drying tower was total, amounted to 48 drying chambers.Be provided with 2 microwave devices (3080) in described each drying chamber (3030).

Embodiment seven:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 100 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 45 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 13mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 13mm with it.

3022,7 sealed gates 3050 of 4 separate layers are arranged in the described casing 301.2 sides, every side were each 4 layers, every layer each 6 about described box type multi-stage drying tower was total, amounted to 48 drying chambers.Be provided with 3 microwave devices (3080) in described each drying chamber (3030).

Embodiment eight:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 105 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 48 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 15mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 15mm with it.

3022,8 sealed gates 3050 of 5 separate layers are arranged in the described casing 301.2 sides, every side were each 5 layers, every layer each 7 about described box type multi-stage drying tower was total, amounted to 70 drying chambers.Be provided with 3 microwave devices (3080) in described each drying chamber (3030).

Embodiment nine:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 110 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 54 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 17mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 17mm with it.

3022,8 sealed gates 3050 of 5 separate layers are arranged in the described casing 301.2 sides, every side were each 5 layers, every layer each 7 about described box type multi-stage drying tower was total, amounted to 70 drying chambers.Be provided with 3 microwave devices (3080) in described each drying chamber (3030).

Embodiment ten:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 115 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 60 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 19mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 19mm with it.

3022,9 sealed gates 3050 of 6 separate layers are arranged in the described casing 301.2 sides, every side were each 6 layers, every layer each 8 about described box type multi-stage drying tower was total, amounted to 96 drying chambers.Be provided with 4 microwave devices (3080) in described each drying chamber (3030).

Embodiment 11:

Adopt following technical parameter to improve embodiment one:

The radian of the arc groove 3046 of described conveyer belt outer surface is 120 °.

The oblique angle c1 on the mutual adaptive inclined-plane of the top gate 3051 of described sealed gate and bottom gate 3052 is 63 °.

The charging port 3061 of described charging aperture 3060 is positioned at conveyer belt 3041 tops, this conveyer belt that is slidingly connected, and maintain the safety clearance of 21mm with it.

The discharging port 3071 of described discharging opening 3070 is positioned at conveyer belt 3041 bottoms, this conveyer belt that is slidingly connected, and maintain the safety clearance of 21mm with it.

3022,10 sealed gates 3050 of 6 separate layers are arranged in the described casing 301.2 sides, every side were each 6 layers, every layer each 9 about described box type multi-stage drying tower was total, amounted to 108 drying chambers.Be provided with 4 microwave devices (3080) in described each drying chamber (3030).

Claims (10)

1. box type multi-stage drying tower with microwave drying, it is characterized in that, comprise casing (301), separating system (302), multistage drying system (303), transfer system (304), sealing system (305), feed system (306), discharge system (307) and microwave drying system (308);

Described casing (301) is the cube structure of a hollow, further comprises top layer (3011) and one group of side door (3012);

Described separating system (302) is positioned at casing (301) inside, comprises a dividing wall (3021) and a component interlayer (3022), is used to separate casing (301);

Described multistage drying system (303) is positioned at casing (301) inside, has one group of drying chamber (3030) that is surrounded by casing (301), separating system (302) and sealing system (305);

Described transfer system (304) is located on each separate layer (3022), is that one group of surface has the conveyer belt system that is used to prevent the arc groove that material slides;

Described feed system (306) connect box (301) front side;

Described discharge system (307) connect box (301) rear side;

Described microwave drying system (308) is arranged on one group of microwave device on the dividing wall (3021), is used for the material in the drying chamber (3030) is evenly dried.

2. the box type multi-stage drying tower with microwave drying as claimed in claim 1, it is characterized in that, described dividing wall (3021) is the hollow wall structure that vertically distributes, and is positioned on the center line of casing (301), and casing (301) is divided into left side casing (3013) and right side casing (3014);

The top layer (3011) of casing (301) is passed on the top (3023) of described dividing wall (3021), is exposed to the outside of casing (301);

Described separate layer (3022) is the planar structure of horizontal distribution, and the position vertically is divided into sandwich construction with casing (301);

Described dividing wall (3021) and each separate layer (3022) are separated into some drying chambers (3030) with casing (301), to form described drying system (303).

3. the box type multi-stage drying tower with microwave drying as claimed in claim 2 is characterized in that, is distributed with one group of pore (3020) on the left side body of wall (3024) of described dividing wall (3021) and the right side body of wall (3025);

Described pore (3020) passes left side body of wall (3024) respectively and right side body of wall (3025) is interconnected with each drying chamber (3030) inside, enter each drying chamber (3030) inside to allow dividing wall (3021) gas inside to pass the outside unidirectional discharge of body of wall, and allow each drying chamber (3030) gas inside to be taken away by pore (3020) by pore (3020);

Have one group of air admission hole (30231) and one group of steam vent (30232) on the top (3023) of described dividing wall (3021), described air admission hole (30231) and steam vent (30232) are communicated with the inside of dividing wall (3021) hollow, are used for taking gas away to its inner input gas with from its inside;

Described separate layer (3022) is connected on the dividing wall (3021), and support on it transfer system (304).

4. the box type multi-stage drying tower with microwave drying as claimed in claim 3 is characterized in that, described transfer system (304) comprises one group of conveyer structure (3040) that is placed on each separate layer (3022); Described conveyer structure (3040) further comprises conveyer belt (3041) and one group of transmission shaft (3042); Described transmission shaft (3042) is used for the conveyer belt on it (3041) is sent to the rear side that casing (301) is connected with discharge system (307) from the front side that casing (301) is connected with feed system (306); Described conveyer belt (3041) comprises one group of opening (3043) that equidistantly distributes and the hermetically-sealed construction (3044) that is positioned at each opening (3043) both sides;

Described conveyer belt (3041) is provided with gear with the inner surface that transmission shaft is in contact with one another, and the gear on this gear and transmission shaft (3042) surface is meshing with each other, to realize synchronous driving;

Described conveyer belt (3041) outer surface has the arc groove (3046) of continuous distributed, slides to prevent the material on it;

Described arc groove (3046) is the arc concave configuration that is surrounded by the most advanced and sophisticated projection (3045) around it, and its radian is 50 °～130 °, is line style at conveyer belt (3041) outer surface along direction of transfer and distributes or matrix distribution.

5. the box type multi-stage drying tower with microwave drying as claimed in claim 4, it is characterized in that described sealing system (305) comprises and is positioned at the inner one group of sealed gate (3050) of casing (301), is positioned at the inner one group of lifting motor (3053) of each sealed gate (3050) and one group of elevating lever (3054) and seals supplementary structure (3055) around on every side one group of each sealed gate (3050);

Described sealed gate (3050) is a kind of movable gate, comprises top gate (3051) and bottom gate (3052);

Described top gate (3051) and bottom gate (3052) have adaptive inclined-plane mutually, are used to carry out the seal closure of gatehouse, and the oblique angle on described inclined-plane is 24 °～66 °;

Described top gate (3051) comprises the inside of bottom (30510), hollow and has the top of opening, and passes through on the separate layer (3022) of top portion fixed thereon;

The inside of described top gate (3051) has the lifting motor (3053) and the elevating lever (3054) that is connected thereon that is installed on the bottom (30510);

Described elevating lever (3054) connects and supports and is positioned at the respective lower gate (3052) of last layer, and drives this bottom gate (3052) and move up and down;

Described bottom gate (3052) is positioned at respective upper gate (3051) inside of one deck down, can pass the opening at top and the respective openings (3043) on the conveyer belt (3041) moves up and down, when rising, pass this opening (3043) and do the inclined-plane seal closure, when descending, pass the inside of respective upper gate (3051) hollow of one deck under this opening (3043) indentation with the respective upper gate (3051) of layer.

6. the box type multi-stage drying tower with microwave drying as claimed in claim 5, it is characterized in that, described sealing supplementary structure (3055) is a kind of closed-in construction, be in the same perpendicular with corresponding sealed gate, be used for sealed gate is connected with on every side body structure, separate layer structure, driving-belt structure, dividing wall sealing structure;

Described supplementary structure (3055) side adjacent with dividing wall (3021) that respectively seal extended and is inserted into dividing wall (3021) inside, and dividing wall (3021) inside is separated into the interior zone that one group of inside is separate, not exchange information, an all corresponding drying chamber (3030) and the drying chamber (3030) that is positioned at its right side that is positioned at its left side of each interior zone, and the respective tops of each interior zone has an air admission hole (30231) and a steam vent (30232).

7. the box type multi-stage drying tower with microwave drying as claimed in claim 6, it is characterized in that described microwave drying system (308) comprises the left side body of wall (3024) that is positioned at dividing wall (3021) and the one group of microwave device (3080) on the right side body of wall (3025);

Described each microwave device (3080) comprises microwave generator and microwave waveguide device, is used for generating and the conduction microwave, to dry the material in each drying chamber;

Be provided with 1～4 microwave device (3080) in described each drying chamber (3030).

8. the box type multi-stage drying tower with microwave drying as claimed in claim 7 is characterized in that, described feed system (306) comprises one group and is positioned at casing (301) front side, and the charging aperture (3060) that is interconnected with each drying chamber of casing front side;

Described charging aperture (3060) is connected on the left upper portion gate (3051) of front side corresponding with it drying chamber;

The charging port (3061) of described charging aperture (3060) is positioned at conveyer belt (3041) top, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it;

Described discharge system (307) comprises one group and is positioned at casing (301) rear side, and the discharging opening (3070) that is interconnected with each drying chamber of casing rear side;

Described discharging opening (3070) is connected on the right upper portion gate (3051) of rear side drying chamber corresponding with it;

The discharging port (3071) of described discharging opening (3070) is positioned at conveyer belt (3041) bottom, this conveyer belt that is slidingly connected, and maintain the safety clearance of 2mm～22mm with it.

9. the box type multi-stage drying tower with microwave drying as claimed in claim 8 is characterized in that, each drying chamber (3030) of described multistage drying system (303) is surrounded by casing (301), separating system (302) and sealing system (305);

The left and right sides of described drying chamber (3030) is that two sealed gates (3050) and two sealing supplementary structure (3055), rear side are that dividing wall (3021), front side are that side door (3012), the end face of casing (301) is that separate layer (3022), bottom surface are conveyer belt (3041), two transmission shafts (3042) and adjacent 4 openings (3043);

The gap width of described opening (3043) equates that with the thickness of sealed gate (3050) gap length of opening equates with its width, so that sealed gate passes opening (3043) and driving fit just; The outside width of described sealing supplementary structure (3055) and conveyer belt (3041) width are equal, inboard width equates with sealed gate (3050) width, height equates with the vertical spacing of separate layer and conveyer belt, be closed into a hermetically-sealed construction so that the sealing supplementary structure can connect dividing wall (3021), demarcation strip (3022), sealed gate (3050), conveyer belt (3041) and opening thereof;

The spacing that is positioned at two adjacent apertures (3043) on the same horizontal plane equates with the spacing of two sealed gates (3050);

Two other opening is overlapping with aforementioned two opening in the vertical directions respectively, so that sealed gate can pass two openings on the vertical direction simultaneously, thereby is retracted to the gate inside, top of lower floor;

Be provided with 2～6 separate layers (3022), 4～10 sealed gates (3050) in the described casing (301), thereby make multistage drying system (303) have 2 * 2 * 3～2 * 6 * 9 drying chambers (3030), and 2 * 2～2 * 6 charging apertures (3060) and 2 * 2～2 * 6 discharging openings (3070).

10. employing such as the residing box type multi-stage drying tower with microwave drying of claim 9 method of drying is characterized in that, comprises following steps:

Step 31:, will material particles be dried be input on the conveyer belt (3041) with the corresponding drying chamber of this charging aperture (3030) by each charging aperture (3060) of feed system (306);

Step 32: conveyer belt (3041) under the drive of transmission shaft (3042), the side shifting backward from the front side of casing (301), in this process, material particles covers full conveyer belt (3041) gradually;

Step 33: conveyer belt (3041) is meshing with each other with the gear of transmission shaft (3042), move to assigned position so that transmission shaft (3042) drives conveyer belt (3041) synchronously, promptly each opening (3043) on the conveyer belt (3041) is overlapping with corresponding sealed gate (3050) in the vertical direction;

Step 34: the inner lifting motor (3053) of following one deck top gate (3051) drive elevating lever (3054) with and go up the bottom gate (3052) that connects and rise, eject from this time one deck top gate (3051) is inner, pass driving-belt (3041) and go up corresponding opening (3043), rise and carry out the inclined-plane seal closure with respective upper gate (3051) with one deck;

Step 35: after treating each sealed gate (3050) closure, oven dry with uniform temperature humidity enters into dividing wall (3021) inside with gas from each air admission hole (30231) on dividing wall (3021) top, discharge by each pore (3020) on left side body of wall (3024) and the right side body of wall (3025) subsequently, so that each airtight interior gassy of relatively independent drying chamber (3030), thereby oven dry material particles;

After drying time finishes, by each steam vent (30232) on dividing wall (3021) top, utilize the above-mentioned pore (302) on the body of wall again, each drying chamber (3030) gas inside is taken away;

Because each drying chamber (3030) is relatively independent and airtight, and described sealing supplementary structure (3055) to be a kind of closed-in construction be separated into the interior zone that one group of inside is separate, not exchange information with dividing wall (3021) inside, and scope that should the zone is identical with the drying chamber scope, so air admission hole and steam vent by each interior zone top can carry out oven dry in various degree to the inner gas that injects different temperatures humidity of each drying chamber;

Step 36: in above-mentioned drying course, energising starts the microwave generator of each microwave drying system (308), produces microwave, and transmits by the microwave waveguide device, thereby to the drying materials on the conveyer belt (3051) in the drying chamber (3030);

Step 37: after the end of waiting to bleed, the inner lifting motor (3053) of following one deck top gate (3051) drive elevating lever (3054) with and go up the bottom gate (3052) that connects and descend, be separated from each other with respective upper gate (3051) with one deck, pass driving-belt (3041) and go up corresponding opening (3043), descend and be retracted to the corresponding hollow inside of one deck top gate (3051) down;

Step 38: this moment, each sealed gate was opened, and conveyer belt (3041) continues to move under the drive of transmission shaft (3042), material particles is sent in the next drying chamber dries;

Step 39: will dry good material particles and output to each discharging opening (3070) of the corresponding discharge system of this conveyer belt (3041) (307) by conveyer belt (3041) and locate, thereby material particles is exported.

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