CN110710579A - Steam hot air water-removing machine - Google Patents

Abstract

The invention provides a steam hot air enzyme deactivating machine, and belongs to the field of tea production equipment. The tea leaf fixation machine solves the problems that an existing fixation machine is low in processing efficiency, tea leaves cannot be processed in a large batch, and the moisture content of the tea leaves is high. The vibration fixation device comprises a rack, a feeding frame, a driving mechanism, a vibration fixation chamber and a housing, wherein the feeding frame, the driving mechanism, the vibration fixation chamber and the housing are arranged on the rack, the vibration fixation chamber is connected with the driving mechanism, the feeding frame is obliquely arranged, the bottom of the feeding frame is connected with the vibration fixation chamber, the vibration fixation chamber can reciprocate along the length direction of the rack under the driving of the driving mechanism and simultaneously drives the feeding frame to move, a plurality of blast ports, a plurality of steam inlets, a plurality of exhaust chimneys and a discharge port are further arranged on the vibration fixation chamber, and the vibration fixation chamber is of a multilayer structure. The invention has the advantages of high processing efficiency and reduced tea moisture.

Description

Steam hot air water-removing machine

Technical Field

The invention relates to the field of tea production equipment, in particular to a steam hot air enzyme deactivating machine.

Background

The tea fixation machine used at present can be divided into a metal heat conduction type and a steam heat conduction type according to different heat conduction modes. The metal heat conduction type is represented by a roller fixation machine, the machine has the advantages of high work efficiency, simplicity in operation and the like, but the fixation quality is unstable, the smoke smell is easily generated, the fixation is not uniform and thorough, and the tea processing amount of the roller fixation machine is too small to meet the processing of a large amount of tea. The steam heat conduction type de-enzyming machine takes saturated steam as a heat transfer medium, the existing problems of the drum-type de-enzyming machine can be solved, but because the water content of the saturated steam is high, the water content of fresh tea leaves can be increased by 10-20% in the steam de-enzyming process, so that the quality of the tea leaves is reduced to some extent, and the quality requirements of the existing tea making process can not be met.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a steam hot air green removing machine which is high in processing efficiency and capable of reducing the moisture of tea leaves.

The purpose of the invention can be realized by the following technical scheme: the utility model provides a hot-blast machine that completes of steam, a serial communication port, including the frame and install feeding frame, actuating mechanism, vibration chamber, the housing that completes in the frame, vibration chamber and actuating mechanism be connected, feeding frame slope set up and the bottom is connected with the vibration chamber that completes, the vibration chamber that completes can be reciprocating motion along frame length direction under the actuating mechanism drive, drive the feeding frame simultaneously and move, the vibration chamber that completes on still be equipped with a plurality of tuyeres, a plurality of steam inlet, a plurality of exhaust chimney and discharge gate, the vibration chamber that completes adopt multilayer structure.

The working principle of the invention is as follows: when tea leaves are subjected to enzyme deactivation processing, tea leaves are transported and poured into the feeding frame, the driving mechanism starts to move to drive the vibration enzyme deactivation chamber to do small-amplitude high-frequency reciprocating motion along the length direction of the rack, the feeding frame moves simultaneously to enable the tea leaves to fall into the vibration enzyme deactivation chamber, the vibration enzyme deactivation chamber continuously vibrates in a high-frequency back and forth mode, air is introduced into the air blowing port, steam is introduced into the steam inlet, the tea leaves continuously move to the discharging port under the motion effects of air flowing in from the air blowing net and the vibration enzyme deactivation chamber, the oxidase activity in the tea leaves is damaged and passivated at high temperature in the process, the enzymatic oxidation of tea polyphenol and the like in the tea leaves is inhibited, partial moisture of the tea leaves is evaporated, the tea leaves are softened, the kneading and forming are convenient, simultaneously, the odor is emitted, and the air outlet can enable overheat steam in. Adopt the setting of above-mentioned structure, adopt multilayer structure can promote the efficiency and the handling capacity of completing of tealeaves greatly, the setting of a plurality of tuyeres simultaneously can be moved the in-process constantly with the tealeaves on the moisture that has and weather up the chimney exhaust of exhausting from the hot-air.

In foretell hot-blast green removing machine of steam, actuating mechanism be eccentric vibration mechanism, eccentric vibration mechanism include driving motor, drive shaft, axle bed, eccentric wheel, connecting portion, stabilizer pulley, driving motor be connected with the drive shaft belt drive, drive shaft swivelling joint on the axle bed, the eccentric wheel install in the drive shaft and with the coaxial rotation of drive shaft, connecting portion one end be connected with the eccentric wheel, one end and vibration green removing room butt, stabilizer pulley install in the drive shaft the other end of band pulley.

In foretell hot-blast machine that completes of steam, the vibration chamber of completing including upper bin, middle level storehouse, the bottom storehouse that communicates in proper order, upper bin, middle level storehouse, bottom storehouse be connected in actuating mechanism respectively, the frame on be equipped with a plurality of vibration shell fragment supports, vibration shell fragment support be used for supporting upper bin, middle level storehouse, bottom storehouse respectively for upper bin, middle level storehouse, bottom storehouse can be followed frame length direction and do reciprocating motion respectively, upper bin, middle level storehouse, bottom storehouse inside all be equipped with a plurality of net of blowing, the net of blowing is used for when the tuyere blows in the air, the air can flow into at the indoor portion of vibration chamber of completing from the net of blowing to the motion of cooperation vibration chamber of completing makes tealeaves remove.

In foretell hot-blast machine that completes of steam, connecting portion include connecting rod, bearing, fixed axle sleeve, installation axle, the connecting rod side on still be equipped with the fixed plate, the bearing be located inside the connecting rod both ends, through the spacing bearing axial motion of fixed plate, connecting portion and eccentric wheel one end of being connected, the bearing inner race sets up with the eccentric wheel outer lane is tangent, it is spacing that the side passes through the fixed plate, the vibration chamber of completing on still be equipped with the stopper, the stopper be used for with the spacing axial displacement of connecting rod, fixed axle sleeve install in installation axle both ends and with the stopper butt, fixed axle sleeve will install the axle fixing through the connecting piece, the stopper link firmly with the vibration chamber of completing through the connecting piece.

In foretell hot-blast machine that completes of steam, the upper storehouse include first frame, first blast chamber, the steam heating chamber that completes, first frame head end that completes be connected with actuating mechanism, the tail end is equipped with first feed opening, first feed opening and middle level storehouse intercommunication, first blast chamber and steam heating chamber be located the below both ends of first frame that completes, first blast chamber on be equipped with a plurality of blast orifices, steam heating chamber top for exhaust chimney position, first blast chamber and steam heating chamber upper surface all be equipped with the blowing net, the steam heating chamber still be connected with steam inlet.

In the above-mentioned hot-blast machine that completes of steam, the middle level storehouse include second frame and the second blast chamber of completing, second frame head end of completing be connected with actuating mechanism to be equipped with the second feed opening at the head end, the second blast chamber be located second frame below of completing, the second blast chamber on be equipped with a plurality of tuyeres.

In the above-mentioned hot-blast machine that completes of steam, the bottom storehouse include third frame and the third blast chamber of completing, third frame head end of completing be connected with actuating mechanism and with second feed opening intercommunication, the tail end and discharge gate intercommunication, the third blast chamber be located third frame below of completing, the third blast chamber on be equipped with a plurality of tuyeres.

In the above-mentioned hot-blast machine that completes of steam, first frame, second frame and the third frame bottom of completing all be equipped with the bottom strengthening rib, and also all be equipped with triangle-shaped strengthening rib with actuating mechanism junction.

In the above hot-air steaming machine, the steam heating chamber is further provided with a heating pipe group, the heating pipe group comprises a heating main pipe and a plurality of small heating pipes with sealed ends and tails, the heating main pipe is communicated with the steam inlet, the steam inlet supports the heating pipe group and enables the heating pipe group to be suspended, the small heating pipes are uniformly arranged on the heating main pipe in parallel along the length direction of the heating main pipe and are communicated with the heating main pipe, the small heating pipes are further provided with a plurality of vent holes, and the side surface of the steam heating chamber is further provided with a standby blast hole.

In the above steam hot air water-removing machine, the exhaust chimney is hermetically connected with the housing or is of an integral structure, the bottom of the exhaust chimney is of an upward convex structure, the exhaust chimney is positioned in the center of the convex, and the lower part of the exhaust chimney is communicated with the vibration water-removing chamber.

Compared with the prior art, the invention has the beneficial effects that: adopt multilayer structure can promote the efficiency and the processingquantity that completes of tealeaves greatly, the setting of a plurality of tuyeres simultaneously, can move the in-process constantly with the moisture that has on the tealeaves at tealeaves and weather up and discharge from the exhaust chimney through the hot-air, vapor heating tube group to wind through the tuyeres insufflates indoor flow in the vibration green-removing, completes tealeaves under the high temperature condition, the greatly reduced moisture increase of tealeaves, satisfy and grind tea processing demand greatly in batches.

Drawings

FIG. 1 is an isometric schematic view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is an isometric cross-sectional view of the present invention;

FIG. 4 is an enlarged partial view of the drive mechanism of the present invention;

FIG. 5 is a schematic cross-sectional view of the present invention;

FIG. 6 is a schematic view of the internal structure of the present invention;

FIG. 7 is an enlarged partial schematic view of the connection of the present invention;

FIG. 8 is a schematic view of the internal construction of the steam heating chamber of the present invention;

in the figure, 1, a frame; 2. a feeding frame; 3. a drive mechanism; 4. a vibration fixation chamber; 5. a housing; 6. a tuyere; 7. a steam inlet; 8. an exhaust stack; 9. a discharge port; 10. an air blowing net; 11. a drive motor; 12. a drive shaft; 13. a shaft seat; 14. an eccentric wheel; 15. a connecting portion; 16. a stabilizing wheel; 17. an upper layer bin; 18. a middle layer bin; 19. a bottom layer bin; 20. vibrating the spring plate support; 21. a connecting rod; 22. a bearing; 23. fixing the shaft sleeve; 24. installing a shaft; 25. a fixing plate; 26. a limiting block; 27. a first de-enzyming frame; 28. a first blast chamber; 29. a steam heating chamber; 30. a first feed opening; 31. a second fixation frame; 32. a second blast chamber; 33. a second feed opening; 34. a third fixation frame; 35. a third blast chamber; 36. a bottom reinforcing rib; 37. triangular reinforcing ribs; 38. a heating pipe group; 39. heating the main pipe; 40. heating the tubule; 41. a vent hole; 42. and (4) a spare blast hole.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1-8, the hot-air steam enzyme-deactivating machine comprises a frame 1, a feeding frame 2, a driving mechanism 3, a vibrating enzyme-deactivating chamber 4 and a housing 5, wherein the feeding frame 2 is mounted on the frame 1, the vibrating enzyme-deactivating chamber 4 is connected with the driving mechanism 3, the feeding frame 2 is obliquely arranged, the bottom of the feeding frame is connected with the vibrating enzyme-deactivating chamber 4, the vibrating enzyme-deactivating chamber 4 can reciprocate along the length direction of the frame 1 under the driving of the driving mechanism 3 and simultaneously drives the feeding frame 2 to move, a plurality of blast ports 6, a plurality of steam inlets 7, a plurality of exhaust chimneys 8 and a discharge port 9 are further arranged on the vibrating enzyme-deactivating chamber 4, and the vibrating enzyme-deactivating chamber 4 adopts a multilayer structure.

In more detail, the driving mechanism 3 is an eccentric vibration mechanism, the eccentric vibration mechanism comprises a driving motor 11, a driving shaft 12, a shaft seat 13, an eccentric wheel 14, a connecting part 15 and a stabilizing wheel 16, the driving motor 11 is in belt transmission connection with the driving shaft 12, the driving shaft 12 is in rotary connection with the shaft seat 13, the eccentric wheel 14 is installed on the driving shaft 12 and rotates coaxially with the driving shaft 12, the connecting part 15 is respectively connected with the eccentric wheel 14 and the vibrating fixation chamber 4, and the stabilizing wheel 16 is installed at the other end of the driving shaft 12, which is provided with a belt wheel. Adopt the setting of above-mentioned structure, driving motor 11 drives drive shaft 12 rotatory, and drive shaft 12 drives eccentric wheel 14 rotatory, and eccentric wheel 14 makes connecting portion 15 constantly carry out reciprocating motion, and connecting portion 15 drives vibration green removing room 4 and the vibration of feeding frame 2 for tealeaves can constantly get into vibration green removing room 4, and the cooperation air-blower removes.

Further, the vibration green-removing chamber 4 comprises an upper layer cabin 17, a middle layer cabin 18 and a bottom layer cabin 19 which are sequentially communicated, the upper layer cabin 17, the middle layer cabin 18 and the bottom layer cabin 19 are respectively connected with the driving mechanism 3, a plurality of vibration elastic sheet supports 20 which are obliquely arranged are arranged on the rack 1, the vibration elastic sheet supports 20 are used for respectively supporting the upper layer cabin 17, the middle layer cabin 18 and the bottom layer cabin 19, the upper layer cabin 17, the middle layer cabin 18 and the bottom layer cabin 19 can respectively do reciprocating motion along the length direction of the rack 1, a plurality of air blowing nets 10 are respectively arranged inside the upper layer cabin 17, the middle layer cabin 18 and the bottom layer cabin 19, and the air blowing nets 10 are used for flowing into the vibration green-removing chamber 4 from the air blowing nets 10 when air is blown into the air blowing ports 6, so that tea leaves can move by matching with the motion of the vibration green-removing. Adopt the setting of above-mentioned structure, can hold more tealeaves and process, the time of completing of tealeaves can be guaranteed simultaneously for tealeaves completes more fully, vibration shell fragment support 20 is preferred to be welded with upper bin 17, middle level storehouse 18, bottom storehouse 19, not only can play the supporting role and can also play the effect that the stroke resets.

Further, it is said in detail that connecting portion 15 includes connecting rod 21, bearing 22, fixed axle sleeve 23, installation axle 24, still be equipped with fixed plate 25 on the connecting rod 21 side, bearing 22 is located inside connecting rod 21 both ends, the axial motion through fixed plate 25 spacing bearing 22, the one end that connecting portion 15 is connected with eccentric wheel 14, bearing 22 inner circle and the tangent setting of eccentric wheel 14 outer lane, the side is spacing through fixed plate 25, still be equipped with stopper 26 on the vibration chamber of completing 4, stopper 26 is used for the spacing axial displacement of connecting rod 21, fixed axle sleeve 23 is installed in installation axle 24 both ends and with stopper 26 butt, fixed axle sleeve 23 is fixed installation axle 24 through the connecting piece, stopper 26 links firmly with vibration chamber of completing 4 through the connecting piece. Adopt the setting of above-mentioned structure, choose for use and can bear radial load and axial load's bearing 22 simultaneously, preferably angular contact ball bearing 22, when eccentric wheel 14 rotated, the bearing 22 inboard received radial force for bearing 22 can drive the motion of connecting rod 21, thereby drives fixed axle sleeve 23 motion, and connecting portion 15 constantly promotes vibration chamber 4 that completes, and cooperation vibration shell fragment support 20 makes the vibration complete and can be reciprocating motion along frame 1 length direction.

In further detail, the upper bin 17 comprises a first green removing frame 27, a first blowing chamber 28 and a steam heating chamber 29, the head end of the first green removing frame 27 is connected with the driving mechanism 3, the tail end of the first green removing frame is provided with a first discharging port 30, the first discharging port 30 is communicated with the middle bin 18, the first blowing chamber 28 and the steam heating chamber 29 are located at two ends below the first green removing frame 27, the first blowing chamber 28 is provided with a plurality of blowing ports 6, an exhaust chimney 8 is located above the steam heating chamber 29, the upper surfaces of the first blowing chamber 28 and the steam heating chamber 29 are both provided with blowing nets 10, and the steam heating chamber 29 is further connected with a steam inlet 7. With the adoption of the structure, when tea leaves enter the first green removing frame 27, the first blast chamber 28 is blasted by the air blower, the steam heating chamber 29 is heated by hot air introduced through the steam inlet 7, so that the temperature in the upper layer cabin 17 rises to form hot air flow, the first green removing frame 27 is driven by the driving mechanism 3 to vibrate continuously, and the first blast chamber 28 and the steam heating chamber 29 cannot move.

In further detail, the middle layer bin 18 includes a second green removing frame 31 and a second blast chamber 32, the head end of the second green removing frame 31 is connected with the driving mechanism 3, and a second feed opening 33 is arranged at the head end, the second blast chamber 32 is located below the second green removing frame 31, and a plurality of blast openings 6 are arranged on the second blast chamber 32. Preferably, the tuyere 6 of the second blast chamber 32 is communicated with the tuyere 6 of the first blast chamber 28, part of the tuyeres 6 of the second tuyere 6 are ventilated, the remaining tuyeres 6 of the first blast chamber 28 and the second tuyere 32 are completely closed, so that the air flow can be from bottom to top, the number of blowers used is reduced, and the second fixation frame 31 can move independently along with the driving mechanism 3.

In further detail, the bottom layer bin 19 comprises a third fixation frame 34 and a third blast chamber 35, the head end of the third fixation frame 34 is connected with the driving mechanism 3 and communicated with the second feed opening 33, the tail end of the third fixation frame is communicated with the discharge opening 9, the third blast chamber 35 is positioned below the third fixation frame 34, and the third blast chamber 35 is provided with a plurality of blast ports 6. Preferably, the tuyere 6 of the third tuyere 35 is blown to completely seal the tuyere 6 not used by the third tuyere 35, and the moisture carried by the tea leaves in the middle and bottom silos 18 and 19 can be guided to the exhaust chimney 8 of the upper silo 17 by using the principle that the hot air ascends.

In order to enhance the structural strength, bottom reinforcing ribs 36 are disposed at the bottoms of the first, second and third fixation frames 27, 31 and 34, and triangular reinforcing ribs 37 are disposed at the joints with the driving mechanism 3.

To be more specific, a heating pipe group 38 is further arranged in the steam heating chamber 29, the heating pipe group 38 comprises a heating main pipe 39 and a plurality of small heating pipes 40 sealed end to end, the heating main pipe 39 is communicated with the steam inlet 7, the steam inlet 7 supports and suspends the heating pipe group 38, the small heating pipes 40 are uniformly arranged on the heating main pipe 39 in parallel along the length direction of the heating main pipe 39 and communicated with the heating main pipe 39, a plurality of vent holes 41 are further formed in the small heating pipes 40, and a spare blast hole 42 is further formed in the side surface of the steam heating chamber 29. With the arrangement of the structure, the steam enters from the steam inlet 7, flows through the heating main pipe 39 and then enters the heating small pipe 40, the contact area of the heating small pipe 40 and the air can be effectively increased, so that the temperature of the steam heating chamber 29 is more uniform, and meanwhile, the spare blast hole 42 can be used for strengthening the air flow of the steam by using a blower when needed.

Preferably, the exhaust chimney 8 is hermetically connected with the housing 5 or is of an integral structure, the bottom of the exhaust chimney 8 is of an upward convex structure, the exhaust chimney 8 is positioned in the center of the convex, and the lower part of the exhaust chimney 8 is communicated with the vibration enzyme deactivation chamber 4. By adopting the structure, certain guide effect can be carried out on the steam, and the discharge of redundant steam is facilitated.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Although the terms of the machine frame 1, the feeding frame 2, the driving mechanism 3, the vibration fixation chamber 4, the housing 5, the blast port 6, the steam inlet 7, the exhaust chimney 8, the discharge port 9, the blowing net 10, the driving motor 11, the driving shaft 12, the shaft seat 13, the eccentric wheel 14, the connecting portion 15, the stabilizing wheel 16, the upper bin 17, the middle bin 18, the lower bin 19, the vibration leaf support 20, the connecting rod 21, the bearing 22, the fixing shaft sleeve 23, the mounting shaft 24, the fixing plate 25, the limiting block 26, the first fixation frame 27, the first blast chamber 28, the steam heating chamber 29, the first discharge port 30, the second fixation frame 31, the second blast chamber 32, the second discharge port 33, the third fixation frame 34, the third blast chamber 35, the bottom reinforcing rib 36, the triangular reinforcing rib 37, the heating pipe group 38, the heating main pipe 39, the heating small pipe 40, the vent hole 41, the spare blast port 42, etc. are used more, but does not exclude the possibility of using other terms. These terms are used merely to more conveniently describe and explain the nature of the present invention; they are to be construed as being without limitation to any additional limitations that may be imposed by the spirit of the present invention.

Claims (10)

1. The utility model provides a hot-blast machine that completes of steam, its characterized in that includes frame (1) and installs feeding frame (2), actuating mechanism (3), vibration chamber (4), housing (5) that completes in frame (1), vibration chamber (4) that completes be connected with actuating mechanism (3), feeding frame (2) slope set up and the bottom is connected with vibration chamber (4) that completes, vibration chamber (4) that completes can be along frame (1) length direction under actuating mechanism (3) drive and be reciprocating motion, drive feeding frame (2) simultaneously and move, vibration chamber (4) that completes on still be equipped with a plurality of blast orifices (6), a plurality of steam inlet (7), a plurality of exhaust chimney (8) and discharge gate (9), vibration chamber (4) that completes adopt multilayer structure.

2. The hot air steaming and green removing machine as claimed in claim 1, wherein the driving mechanism (3) is an eccentric vibration mechanism, the eccentric vibration mechanism comprises a driving motor (11), a driving shaft (12), a shaft seat (13), an eccentric wheel (14), a connecting part (15) and a stabilizing wheel (16), the driving motor (11) is in belt transmission connection with the driving shaft (12), the driving shaft (12) is rotatably connected with the shaft seat (13), the eccentric wheel (14) is mounted on the driving shaft (12) and coaxially rotates with the driving shaft (12), one end of the connecting part (15) is connected with the eccentric wheel (14), and the other end is abutted against the vibrating green removing chamber (4), and the stabilizing wheel (16) is mounted at the other end of the driving shaft (12) provided with a belt wheel.

3. The hot air steam fixation machine as claimed in claim 1, wherein the vibration fixation chamber (4) comprises an upper layer bin (17), a middle layer bin (18) and a bottom layer bin (19) which are sequentially communicated, the upper layer bin (17), the middle layer bin (18) and the bottom layer bin (19) are respectively connected with a driving mechanism (3), the frame (1) is provided with a plurality of vibration spring plate supports (20), the vibration spring plate supports (20) are used for respectively supporting the upper layer bin (17), the middle layer bin (18) and the bottom layer bin (19), so that the upper layer bin (17), the middle layer bin (18) and the bottom layer bin (19) can respectively do reciprocating motion along the length direction of the frame (1), a plurality of air blowing nets (10) are respectively arranged inside the upper layer bin (17), the middle layer bin (18) and the bottom layer bin (19), and the air blowing nets (10) are used for blowing air into the air blowing port (6), air can flow into the vibrating enzyme-deactivating chamber (4) from the air blowing net (10) and flow inside the vibrating enzyme-deactivating chamber, so that the tea leaves are moved by matching with the movement of the vibrating enzyme-deactivating chamber (4).

4. The steam hot air de-enzyming machine as claimed in claim 2, wherein the connecting portion (15) comprises a connecting rod (21), a bearing (22), a fixed shaft sleeve (23) and a mounting shaft (24), a fixing plate (25) is further arranged on the side surface of the connecting rod (21), the bearing (22) is positioned inside two ends of the connecting rod (21), the bearing (22) is limited to move axially through the fixing plate (25), the connecting portion (15) is connected with one end of the eccentric wheel (14), the inner ring of the bearing (22) is arranged in a tangent manner with the outer ring of the eccentric wheel (14), the side surface is limited through the fixing plate (25), a limiting block (26) is further arranged on the vibration de-enzyming chamber (4), the limiting block (26) is used for limiting the connecting rod (21) to move axially, the fixed shaft sleeve (23) is mounted at two ends of the mounting shaft (24) and is abutted against the limiting block, the fixed shaft sleeve (23) fixes the mounting shaft (24) through a connecting piece, and the limiting block (26) is fixedly connected with the vibration fixation chamber (4) through the connecting piece.

5. The machine according to claim 3, characterized in that the upper chamber (17) comprises a first de-enzyming frame (27), a first blast chamber (28), a steam heating chamber (29), the head end of the first green removing frame (27) is connected with the driving mechanism (3), the tail end is provided with a first feed opening (30), the first feed opening (30) is communicated with the middle layer bin (18), the first blast chamber (28) and the steam heating chamber (29) are positioned at the two ends below the first green removing frame (27), a plurality of blast ports (6) are arranged on the first blast chamber (28), an exhaust chimney (8) is arranged above the steam heating chamber (29), the upper surfaces of the first blast chamber (28) and the steam heating chamber (29) are both provided with a blowing net (10), and the steam heating chamber (29) is also connected with a steam inlet (7).

6. The hot air steam fixation machine as claimed in claim 5, wherein the middle layer bin (18) comprises a second fixation frame (31) and a second blast chamber (32), the head end of the second fixation frame (31) is connected with the driving mechanism (3), a second feed opening (33) is arranged at the head end, the second blast chamber (32) is positioned below the second fixation frame (31), and a plurality of blast openings (6) are arranged on the second blast chamber (32).

7. The hot air steam fixation machine as claimed in claim 6, wherein the bottom bin (19) comprises a third fixation frame (34) and a third blast chamber (35), the head end of the third fixation frame (34) is connected with the driving mechanism (3) and communicated with the second feed opening (33), the tail end of the third fixation frame is communicated with the discharge opening (9), the third blast chamber (35) is located below the third fixation frame (34), and a plurality of blast ports (6) are arranged on the third blast chamber (35).

8. The steam hot air de-enzyming machine as claimed in claim 7, wherein bottom reinforcing ribs (36) are arranged at the bottoms of the first de-enzyming frame (27), the second de-enzyming frame (31) and the third de-enzyming frame (34), and triangular reinforcing ribs (37) are arranged at the joints with the driving mechanism (3).

9. The hot air steaming machine according to claim 5, wherein a heating pipe group (38) is further arranged in the steam heating chamber (29), the heating pipe group (38) comprises a heating main pipe (39) and a plurality of small heating pipes (40) sealed end to end, the heating main pipe (39) is communicated with the steam inlet (7), the steam inlet (7) supports the heating pipe group (38) and enables the heating pipe group to suspend in the air, the small heating pipes (40) are uniformly arranged on the heating main pipe (39) in parallel along the length direction of the heating main pipe (39) and communicated with the heating main pipe (39), a plurality of vent holes (41) are further formed in the small heating pipes (40), and a standby blast hole (42) is further formed in the side surface of the steam heating chamber (29).

10. The hot air steam enzyme-deactivating machine of claim 1, wherein the exhaust chimney (8) is hermetically connected with the housing (5) or is of an integral structure, the bottom of the exhaust chimney (8) is of an upward convex structure, the exhaust chimney (8) is positioned in the center of the convex, and the lower part of the exhaust chimney (8) is communicated with the vibration enzyme-deactivating chamber (4).

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