CN201563582U - Transmission system of extruding machine - Google Patents

Abstract

The utility model discloses a transmission system of an extruding machine. The transmission system is positioned on the adjacent sides of the double-screw or multi-screw extruding machine and a discharge opening provided with a cutting blade, and is used for transmitting particles extruded by the extruding machine and pelletized by the cutting blade of the discharge opening and performing coating and drying treatment. The transmission system comprises a particle anti-spattering device, a primary transmission device, a functional transmission device and a long-distance transmission device, and further comprises a coating device and a drying device which are positioned above the functional transmission device.

Description

Extruder conveying system

Technical field

The utility model relates to a kind of transfer system, particularly a kind of extruder conveying system.

Background technology

Along with increase day by day to the requirement of the nutrition of food, the bread basket and the production method thereof of various composite nutrients are also developing by leaps and bounds, from the pre-steaming method technology of early stage acid, directly soak technologies such as suction method and coating method, develop into nowadays more complete:, obtain the technological process of multi-nutrient fortification composite cereal at last from cereal pulverizing → preliminary treatment → mix with nutrient → push → excision forming → drying → screening → join rice in proportion.

And the step of extruding-excision forming wherein is the important step in the production process, single screw rod or the twin (double) screw extruder generally taked, the hydrate of cereal powder is pushed the back by certain shape mould, obtain the cereals of needed shape, size through cutting, and on corresponding conveyer belt, carry, until check and packaging step.

Yet the particle surface that extruder is extruded usually can chap even fragmentation because of the lost generation of moisture in the dry run subsequently, thereby influences the quality of Nutritive Rice or nutrient grain product.

In order to address the above problem, the utility model provides a kind of extruder conveying system, have and apply and drying function, it is before the particle that extruder is extruded is sent to drying system, in transport process, at particle surface coating oil lipid material, and after coating, adopt hot-air, thereby the oil substances that makes particle surface apply solidify rapidly to its rapid oven dry.Enter drying system particle before like this and just had the layer of oil and fat coating, thereby in dry run, can avoid crack performance effectively.

Summary of the invention

The utility model discloses a kind of extruder conveying system, it is positioned at twin-screw or multi-screw extruder and has the adjacent side of the discharging opening of cutter, is used for extruding through extruder and sending away and do coating and oven dry processing through the particle that the discharging opening cutter are granulated.

Described transfer system comprises particle anti-splash out device, elementary conveyer, function conveyer, long apart from conveyer.

Described particle anti-splash out device is positioned at the top of elementary conveyer, and discharging opening is included in its inside.Described particle anti-splash out device comprises back side shield, top flap and two side direction baffle plates.

Described back side shield is an inverted trapezium structure, and the length of the minor face of its bottom is less than the horizontal length of the conveyer belt of elementary conveyer.Be provided with the gap of 30mm～130mm between the bottom of described back side shield and the plane belt of elementary conveyer.Described top flap is extended, is higher than and the extend through discharging opening to the discharging opening top from the top of back side shield, thereby discharging opening is covered its underpart.The horizontal length of described top flap is greater than the horizontal length of discharging opening.Described two side direction baffle plates are inwardly derived downwards from the both sides of top flap, and the two terminal level interval is less than the horizontal length of the conveyer belt of elementary conveyer.

Described each conveyer is followed successively by elementary conveyer, function conveyer and long apart from conveyer along the material direction of transfer.

Described elementary conveyer comprises transmission shaft and plane belt.The inner surface that the plane belt of described elementary conveyer 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 elementary conveyer is positioned at described discharging opening below, and the gap of 10mm～100mm with interval, and overlapping about the front end of described elementary conveyer and the discharging opening, to guarantee that material all drops on the elementary conveyer.The length of described lap is less than 1/10 of elementary conveyer horizontal length.

Described function conveyer comprises transmission shaft and plane belt.The inner surface that the plane belt of function conveyer 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 function conveyer is positioned at elementary conveyer below, and the gap of 10mm～100mm with interval, and the front end of the end of described elementary conveyer and function conveyer is overlapping up and down, and the length of lap is less than 1/10 of function conveyer horizontal length.

Described length comprises at least 3 transmission shafts and long apart from conveyer belt apart from conveyer.Described length is provided with gear apart from the length of conveyer apart from the inner surface that conveyer belt and transmission shaft are in contact with one another, and the gear on this gear and transmission shaft surface is meshing with each other, to realize synchronous driving.

The arc groove that described length has continuous distributed apart from the conveyer belt outer surface slides to prevent the material on it.Described arc groove is that its radian is 50 °～130 ° by most advanced and sophisticated projection around it and the arc concave configuration that is surrounded, and is line style distribution or matrix distribution apart from the conveyer belt outer surface along direction of transfer long.

Described length is positioned at function conveyer below apart from conveyer, and the gap of 10mm～100mm with interval, and the end of described function conveyer is overlapping up and down with long front end apart from conveyer, and the length of lap is less than 1/10 of function conveyer horizontal length.

Described transfer system further comprises coating unit and drying unit.Along flow direction of material, the adjacent successively top that is arranged on the function conveyer of described coating unit and drying unit, the two contour and and the plane belt of function conveyer between the gap of 100mm～300mm at interval.

Described coating unit comprises conveying pipeline and spray material port from top to bottom, and described spray material port is used for material with conveying pipeline and evenly is sprayed on particle on the plane belt that is positioned at the function conveyer.

Described drying unit comprises breather pipe and exhaust outlet from top to bottom, and described exhaust outlet is at a high speed evenly ejection of the hot-air in the breather pipe, thus the particle on the dry plane belt that is positioned at the function conveyer.

Below; to be described further by specific embodiment; yet embodiment only is giving an example of the optional embodiment of the utility model, and its disclosed feature only is used for explanation and sets forth the technical solution of the utility model, and is not used in qualification protection domain of the present utility model.

Description of drawings

Fig. 1 is the overall structure sketch of transfer system of the present utility model.

Fig. 2 is the vertical view of each conveyer belt of transfer system of the present utility model.

Fig. 3 is the structural representation of length of the present utility model apart from the conveyer belt of conveyer.

Fig. 4 a is a length of the present utility model apart from one of arc groove structural representation of the conveyer belt of conveyer.

Fig. 4 b is a length of the present utility model apart from two of the arc groove structural representation of the conveyer belt of conveyer.

Fig. 4 c is a length of the present utility model apart from three of the arc groove structural representation of the conveyer belt of conveyer.

Fig. 5 is the structural representation along the utility model particle anti-splash out device of the A-A ' of Fig. 1.

The specific embodiment

According to claim of the present utility model and the disclosed content of specification, the technical solution of the utility model is specific as follows described:

Embodiment one:

As shown in Figure 1, a kind of extruder conveying system is positioned at twin-screw or multi-screw extruder 11 and has the adjacent side of the discharging opening 12 of cutter, is used for extruder 11 being extruded and the particle that discharging opening 12 cutter are granulated being sent away and do coating and oven dry processing.

Described transfer system comprises particle anti-splash out device 2, elementary conveyer 31, function conveyer, long apart from conveyer 34.

As Fig. 1 and shown in Figure 5, described particle anti-splash out device 2 is included in its inside with discharging opening 12.Described particle anti-splash out device 2 comprises back side shield 21, top flap 22 and two side direction baffle plates 23.

Described back side shield 21 is inverted trapezium structures, and the length of the minor face of its bottom is less than the horizontal length of the conveyer belt 312 of elementary conveyer 31.Be provided with the gap of 30mm～130mm between the bottom of described back side shield 21 and the plane belt 312 of elementary conveyer 31.Described top flap 22 is extended, is higher than and extend through discharging opening 12 to discharging opening 12 tops from the top of back side shield 21, thereby discharging opening 12 is covered its underpart.The horizontal length of described top flap 22 is greater than the horizontal length of discharging opening 12.Described two side direction baffle plates 23 are inwardly derived downwards from the both sides of top flap 22, and the two terminal level interval is less than the horizontal length of the conveyer belt 312 of elementary conveyer 31.

As depicted in figs. 1 and 2, described each conveyer is followed successively by elementary conveyer 31, function conveyer and long apart from conveyer 34 along the material direction of transfer, and the horizontal length of each conveyer increases successively.

Described elementary conveyer 31 comprises transmission shaft 311 and plane belt 312.The inner surface that the plane belt 312 and the transmission shaft 311 of described elementary conveyer 31 are in contact with one another is provided with gear, and the gear on this gear and transmission shaft 311 surfaces is meshing with each other, to realize synchronous driving.

Described elementary conveyer 31 is positioned at described discharging opening 12 belows, and the gap of 10mm～100mm with interval, and the front end of described elementary conveyer 31 and discharging opening are overlapping about in the of 12, to guarantee that material all drops on the elementary conveyer 31.The length of described lap is less than 1/10 of elementary conveyer 31 horizontal lengths.

Described function conveyer comprises transmission shaft 321 and plane belt 322.The inner surface that the plane belt 322 and the transmission shaft 321 of function conveyer are in contact with one another is provided with gear, and the gear on this gear and transmission shaft 321 surfaces is meshing with each other, to realize synchronous driving.

Described function conveyer is positioned at elementary conveyer 31 belows, and the gap of 10mm～100mm with interval, and the front end of the end of described elementary conveyer 31 and function conveyer is overlapping up and down, and the length of lap is less than 1/10 of function conveyer horizontal length.

Described length comprises at least 3 transmission shafts 341 and long apart from conveyer belt 342 apart from conveyer 34.Described length is provided with gear apart from the length of conveyer 34 apart from the inner surface that conveyer belt 342 and transmission shaft 341 are in contact with one another, and the gear on this gear and transmission shaft 341 surfaces is meshing with each other, to realize synchronous driving.

Shown in Fig. 3, Fig. 4 a～4c, the arc groove 345 that described length has continuous distributed apart from conveyer belt 342 outer surfaces slides to prevent the material on it.Described arc groove 345 is by the most advanced and sophisticated projection 343 around it, the 344 arc concave configuration that surrounded, its radian is 50 °～130 °, is shown in line style distribution (shown in Fig. 4 b) or the matrix distribution (as Fig. 4 c) along direction of transfer apart from conveyer belt 342 outer surfaces long.

Described length is positioned at function conveyer below apart from conveyer 34, and the gap of 10mm～100mm with interval, and the end of described function conveyer is overlapping up and down with long front end apart from conveyer 34, and the length of lap is less than 1/10 of function conveyer horizontal length.

As shown in Figure 1, described transfer system further comprises coating unit 41 and drying unit 51.Along flow direction of material, the adjacent successively top that is arranged on the function conveyer of described coating unit 41 and drying unit 51, the two contour and and the plane belt 322 of function conveyer between the gap of 100mm～300mm at interval.

Described coating unit 41 comprises conveying pipeline 411 and spray material port 412 from top to bottom, and described spray material port 412 is used for material with conveying pipeline 411 and evenly is sprayed on particle on the plane belt 322 that is positioned at the function conveyer.

Described drying unit 51 comprises breather pipe 511 and exhaust outlet 512 from top to bottom, and described exhaust outlet 512 is at a high speed evenly ejection of the hot-air in the breather pipe 511, thus the particle on the dry plane belt 322 that is positioned at the function conveyer.

Embodiment two:

On the basis of embodiment one, improve technical scheme in such a way:

Described transfer system further comprises two structure identical functions conveyers, i.e. the first function conveyer 32 and the second function conveyer 33.

The described first function conveyer 32 comprises the plane belt 322 at least 2 transmission shafts 321 and its outside.The inner surface that the plane belt 322 and the transmission shaft 321 of the described first function conveyer 32 are in contact with one another is provided with gear, and the gear on this gear and transmission shaft 321 surfaces is meshing with each other, to realize synchronous driving.

The described second function conveyer 33 comprises the plane belt 332 at least 2 transmission shafts 331 and its outside.The inner surface that the plane belt 332 and the transmission shaft 331 of the described second function conveyer 33 are in contact with one another is provided with gear, and the gear on this gear and transmission shaft 331 surfaces is meshing with each other, to realize synchronous driving.

The described first function conveyer 32 is positioned at elementary conveyer 31 belows, and the gap of 10mm～100mm with interval, and the front end of the end of described elementary conveyer 31 and the first function conveyer 32 is overlapping up and down, and the length of lap is less than 1/10 of the first function conveyer, 32 horizontal lengths.

The described second function conveyer 33 is positioned at the first function conveyer, 32 belows, and the gap of 10mm～100mm with interval, and the front end of the end of the described first function conveyer 32 and the second function conveyer 33 is overlapping up and down, and the length of lap is less than 1/10 of the second function conveyer, 33 horizontal lengths.

Described length is positioned at the second function conveyer, 33 belows apart from conveyer 34, and the gap of 10mm～100mm with interval, and the end of the described second function conveyer 33 is overlapping up and down with long front end apart from conveyer 34, and the length of lap is less than 1/10 of the second function conveyer, 33 horizontal lengths.

Described transfer system further comprises first coating unit 41, second coating unit 42, first drying unit 51 and second drying unit 52.

Along flow direction of material, the adjacent successively top that is arranged on the first function conveyer 32 of described first coating unit 41 with first drying unit 51, the two contour and and the plane belt 322 of the first function conveyer 32 between the gap of 100mm～300mm at interval.

Along flow direction of material, the adjacent successively top that is arranged on the second function conveyer 33 of described second coating unit 42 with second drying unit 52, the two contour and and the plane belt 332 of the second function conveyer 33 between the gap of 100mm～300mm at interval.

Described first coating unit 41 comprises conveying pipeline 411 and spray material port 412 from top to bottom, and described second coating unit 42 comprises conveying pipeline 421 and spray material port 422 from top to bottom.Described spray material port 412,422 is respectively applied for the material in the conveying pipeline 411,421 evenly is sprayed on the particle that is positioned on the plane belt 322,332.

Described first drying unit 51 comprises breather pipe 511 and exhaust outlet 512 from top to bottom, and described second drying unit 52 comprises breather pipe 521 and exhaust outlet 522 from top to bottom.Described exhaust outlet 512,522 is respectively with the evenly ejection at a high speed of the hot-air in breather pipe 511 and 521, thereby drying is positioned at the particle on the plane belt 322,332.

Embodiment three:

In actual use, the material of extruding from extruder 11 advanced the cutting of the cutter of discharging opening 12, form particle, and penetrate, part drops on the conveyer belt 312 of elementary conveyer 31, part is blocked by the back side shield 21 of particle anti-splash out device 2, top flap 22 and two side direction baffle plates 23, thereby drops on the conveyer belt 312 of elementary conveyer 31.Described conveyer belt 312 rotates forward and material is transferred to the end of elementary conveyer 31 under the drive of transmission shaft 311, drops on subsequently on the conveyer belt 322 of the first function conveyer 32.

The transmission shaft 321 of the first function conveyer 32 drives conveyer belt 322 and rotates, and the particle band on it is moved to its end.In the process that transmits, when particle during through first coating unit 41, conveying pipeline 411 is carried the oil substances that applies usefulness, and through spray material port 412 at a high speed, evenly ejection, be coated in the outer surface of each particle.Particle is continued to transmit through first drying unit 51 subsequently, breather pipe 511 is carried the hot-air of oven dry usefulness, and, will be coated in the oil substances baking and curing of particle outer surface before rapidly, thereby form the layer of oil and fat coating at the particle outer surface through exhaust outlet 512 high speeds, evenly ejection.Subsequently, particle is shifted to its end, and is dropped on the conveyer belt 332 of the second function conveyer 33 under conveyer belt 322 drives.

The transmission shaft 331 of the second function conveyer 33 drives conveyer belt 332 and rotates, and the particle band on it is moved to its end.In the process that transmits, when particle during through second coating unit 42, conveying pipeline 421 is carried the oil substances that applies usefulness, and through spray material port 422 at a high speed, evenly ejection, be coated in the outer surface of each particle.Particle is continued to transmit through second drying unit 52 subsequently, breather pipe 521 is carried the hot-air of oven dry usefulness, and, will be coated in the oil substances baking and curing of particle outer surface before rapidly, thereby form the layer of oil and fat coating at the particle outer surface through exhaust outlet 522 high speeds, evenly ejection.Subsequently, particle is shifted to its end under conveyer belt 332 drives, and drops on the long conveyer belt 342 apart from conveyer 34.

Described length is provided with some arc grooves apart from the conveyer belt 342 of conveyer 34, and it has linear structure or the matrix structure shown in Fig. 4 c shown in Fig. 4 b, and particle drops on each arc groove inside.Described length is constantly shaken apart from conveyer, avoid temperature higher, firm through the particle that applies owing to fail bone dry or apply not exclusively and long-time mutually near boning between the particle that causes.In above-mentioned concussion process, arc groove has avoided the particle landing to go out conveyer belt effectively.Particle, along with the conveyer belt 342 that transmission shaft 341 is driven is shifted to long end apart from conveyer 34 and is exported through long concussion apart from conveyer.

Foregoing is exemplifying of specific embodiment of the utility model, for the wherein not equipment of detailed description and structure, should be understood to take existing common apparatus in this area and universal method to be implemented.

Claims (10)

1. an extruder conveying system is characterized in that, comprises with the lower part:

Particle anti-splash out device (2), described particle anti-splash out device (2) comprise back side shield (21), top flap (22) and two side direction baffle plates (23);

Elementary conveyer (31), described elementary conveyer (31) comprise transmission shaft (311) and plane belt (312); Function conveyer, described function conveyer comprise transmission shaft (321) and plane belt (322);

Long apart from conveyer (34), described length comprises at least 3 transmission shafts (341) and long apart from conveyer belt (342) apart from conveyer (34);

Described particle anti-splash out device (2) is positioned at the top of elementary conveyer (31), and is provided with the gap of 30mm～130mm thereafter between the plane belt (312) of the bottom of side shield (21) and elementary conveyer (31);

Described each conveyer is followed successively by elementary conveyer (31), function conveyer and long apart from conveyer (34) along the material direction of transfer;

Described function conveyer is positioned at elementary conveyer (31) below, and the gap of 10mm～100mm with interval, and the end of described elementary conveyer (31) and the front end of function conveyer are overlapping up and down, and the length of lap is less than 1/10 of function conveyer horizontal length;

Described length is positioned at function conveyer below apart from conveyer (34), and the gap of 10mm～100mm with interval, and the end of described function conveyer is overlapping up and down with long front end apart from conveyer (34), and the length of lap is less than 1/10 of function conveyer horizontal length.

2. transfer system as claimed in claim 1, it is characterized in that, it is positioned at twin-screw or multi-screw extruder (11) and has the adjacent side of the discharging opening (12) of cutter, is used for extruder (11) being extruded and the particle that discharging opening (12) cutter are granulated being sent away and do coating and oven dry processing;

Described particle anti-splash out device (2) is included in its inside with discharging opening (12);

Described back side shield (21) is an inverted trapezium structure, and the length of the minor face of its bottom is less than the horizontal length of the conveyer belt (312) of elementary conveyer (31);

Described top flap (22) is extended, is higher than and extend through discharging opening (12) to discharging opening (12) top from the top of back side shield (21), thereby discharging opening (12) is covered its underpart;

The horizontal length of described top flap (22) is greater than the horizontal length of discharging opening (12);

Described two side direction baffle plates (23) are inwardly derived downwards from the both sides of top flap (22), and the two terminal level interval is less than the horizontal length of the conveyer belt (312) of elementary conveyer (31).

3. transfer system as claimed in claim 2, it is characterized in that, described elementary conveyer (31) is positioned at described discharging opening (12) below, and the gap of 10mm～100mm with interval, and the front end of described elementary conveyer (31) and discharging opening (12) are overlapping up and down, to guarantee that material all drops on the elementary conveyer (31); The length of described lap is less than 1/10 of elementary conveyer (31) horizontal length.

4. transfer system as claimed in claim 1, it is characterized in that, the plane belt (312) of described elementary conveyer (31) is provided with gear with the inner surface that transmission shaft (311) is in contact with one another, and the gear on this gear and transmission shaft (311) surface is meshing with each other, to realize synchronous driving.

5. transfer system as claimed in claim 1, it is characterized in that, the plane belt of function conveyer (322) is provided with gear with the inner surface that transmission shaft (321) is in contact with one another, and the gear on this gear and transmission shaft (321) surface is meshing with each other, to realize synchronous driving.

6. transfer system as claimed in claim 1, it is characterized in that, described length is provided with gear apart from the length of conveyer (34) apart from the inner surface that conveyer belt (342) and transmission shaft (341) are in contact with one another, and the gear on this gear and transmission shaft (341) surface is meshing with each other, to realize synchronous driving;

The arc groove (345) that described length has continuous distributed apart from conveyer belt (342) outer surface slides to prevent the material on it;

Described arc groove (345) is the arc concave configuration that is surrounded by the most advanced and sophisticated projection (343,344) around it, and its radian is 50 °～130 °, is line style distribution or matrix distribution apart from conveyer belt (342) outer surface along direction of transfer long.

7. transfer system as claimed in claim 1 is characterized in that, described transfer system further comprises coating unit (41) and drying unit (51);

Along flow direction of material, the adjacent successively top that is arranged on the function conveyer of described coating unit (41) with drying unit (51), the two contour and and the plane belt (322) of function conveyer between the gap of 100mm～300mm at interval;

Described coating unit (41) comprises conveying pipeline (411) and spray material port (412) from top to bottom, and described spray material port (412) is used for material with conveying pipeline (411) and evenly is sprayed on particle on the plane belt (322) that is positioned at the function conveyer;

Described drying unit (51) comprises breather pipe (511) and exhaust outlet (512) from top to bottom, described exhaust outlet (512) is at a high speed evenly ejection of the hot-air in the breather pipe (511), thus the particle on the dry plane belt (322) that is positioned at the function conveyer.

8. transfer system as claimed in claim 1 is characterized in that, described transfer system further comprises two structure identical functions conveyers, i.e. the first function conveyer (32) and the second function conveyer (33);

The described first function conveyer (32) comprises the plane belt (322) at least 2 transmission shafts (321) and its outside;

The plane belt (322) of the described first function conveyer (32) is provided with gear with the inner surface that transmission shaft (321) is in contact with one another, and the gear on this gear and transmission shaft (321) surface is meshing with each other, to realize synchronous driving;

The described second function conveyer (33) comprises the plane belt (332) at least 2 transmission shafts (331) and its outside;

The plane belt (332) of the described second function conveyer (33) is provided with gear with the inner surface that transmission shaft (331) is in contact with one another, and the gear on this gear and transmission shaft (331) surface is meshing with each other, to realize synchronous driving.

9. transfer system as claimed in claim 8, it is characterized in that, the described first function conveyer (32) is positioned at elementary conveyer (31) below, and the gap of 10mm～100mm with interval, and the front end of the end of described elementary conveyer (31) and the first function conveyer (32) is overlapping up and down, and the length of lap is less than 1/10 of first function conveyer (32) horizontal length;

The described second function conveyer (33) is positioned at the first function conveyer (32) below, and the gap of 10mm～100mm with interval, and the front end of the end of the described first function conveyer (32) and the second function conveyer (33) is overlapping up and down, and the length of lap is less than 1/10 of second function conveyer (33) horizontal length;

Described length is positioned at the second function conveyer (33) below apart from conveyer (34), and the gap of 10mm～100mm with interval, and the end of the described second function conveyer (33) is overlapping up and down with long front end apart from conveyer (34), and the length of lap is less than 1/10 of second function conveyer (33) horizontal length.

10. transfer system as claimed in claim 8 is characterized in that, described transfer system further comprises first coating unit (41), second coating unit (42), first drying unit (51) and second drying unit (52);

Along flow direction of material, the adjacent successively top that is arranged on the first function conveyer (32) of described first coating unit (41) with first drying unit (51), the two contour and and the plane belt (322) of the first function conveyer (32) between the gap of 100mm～300mm at interval;

Along flow direction of material, the adjacent successively top that is arranged on the second function conveyer (33) of described second coating unit (42) with second drying unit (52), the two contour and and the plane belt (332) of the second function conveyer (33) between the gap of 100mm～300mm at interval;

Described first coating unit (41) comprises conveying pipeline (411) and spray material port (412) from top to bottom, and described second coating unit (42) comprises conveying pipeline (421) and spray material port (422) from top to bottom;

Described spray material port (412,422) is respectively applied for the material in the conveying pipeline (411,421) evenly is sprayed on the particle that is positioned on the plane belt (322,332);

Described first drying unit (51) comprises breather pipe (511) and exhaust outlet (512) from top to bottom, and described second drying unit (52) comprises breather pipe (521) and exhaust outlet (522) from top to bottom;

Described exhaust outlet (512) and (522) are respectively with the evenly ejection at a high speed of the hot-air in the breather pipe (511,521), thereby drying is positioned at the particle on the plane belt (32,332).

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