CN110849133A

CN110849133A - Energy-conserving gynostemma pentaphylla drying furnace

Info

Publication number: CN110849133A
Application number: CN201911263685.8A
Authority: CN
Inventors: 胡伟
Original assignee: Zhuxi Zhong Chuang Rural E-Commerce Incubator Co Ltd
Current assignee: Zhuxi Zhong Chuang Rural E-Commerce Incubator Co Ltd
Priority date: 2019-12-11
Filing date: 2019-12-11
Publication date: 2020-02-28

Abstract

The invention discloses an energy-saving gynostemma pentaphylla drying furnace, which comprises a furnace body, wherein a drying chamber is arranged in the furnace body, two rotating shafts are rotatably connected to the inner walls of two sides of the drying chamber, two belt pulleys are fixedly sleeved on the corresponding positions of the two rotating shafts, two belt pulleys which are respectively positioned on the two rotating shafts and correspond to the two rotating shafts are jointly tensioned and sleeved with synchronous belts, a mesh belt is jointly and fixedly connected between the two synchronous belts, one end of one rotating shaft penetrates through the drying chamber and is fixedly connected with a first motor, the first motor is fixedly arranged on the furnace body, a heating plate is arranged on the inner wall of the drying chamber and on the inner side of the mesh belt, and a turn-over device is arranged on the inner top. Has the advantages that: air that will dry the room heated through the fan of selecting materials is pumped to dehydrating unit and is got rid of steam to utilize the hot-air after the dehumidification to carry out the selection by winnowing to the gynostemma pentaphylla, avoid the direct wasting of resources that gets into the atmosphere and bring of hot-air, and automatically dehumidify the operation to the dry room.

Description

Energy-conserving gynostemma pentaphylla drying furnace

Technical Field

The invention relates to the technical field of drying furnaces, in particular to an energy-saving gynostemma pentaphylla drying furnace.

Background

Gynostemma pentaphylla is one of the traditional Chinese medicines, and has the effects of reducing blood fat, regulating blood pressure, preventing and treating thrombus, preventing and treating cardiovascular diseases, reducing blood pressure and promoting sleep. In the production of the gynostemma pentaphylla, in order to remove moisture from the gynostemma pentaphylla, a drying oven is generally used to dry the gynostemma pentaphylla.

The existing drying oven dries the gynostemma pentaphylla by heating air and utilizing heated high-temperature air, and steam is directly discharged into the atmosphere under the action of a blower, so that resource waste and environment pollution are caused.

Disclosure of Invention

The invention aims to solve the problems in the background art and provides an energy-saving gynostemma pentaphylla drying furnace.

In order to achieve the purpose, the invention adopts the following technical scheme: an energy-saving gynostemma pentaphylla drying furnace comprises a furnace body, wherein a drying chamber is arranged in the furnace body, two rotating shafts are rotatably connected to the inner walls of two sides of the drying chamber, two belt pulleys are fixedly sleeved on the corresponding positions of the two rotating shafts, two belt pulleys which are respectively positioned on the two rotating shafts and correspond to the two rotating shafts are jointly tensioned and sleeved with synchronous belts, a mesh belt is jointly and fixedly connected between the two synchronous belts, one end of one rotating shaft penetrates through the drying chamber and is fixedly connected with a first motor, the first motor is fixedly installed on the furnace body, a heating plate is installed on the inner wall of the drying chamber and on the inner side of the mesh belt, and a turn-over device is arranged on the inner top wall; a first air suction pipe is hermetically communicated with the right side of the mesh belt on the inner top wall of the drying chamber, the first air suction pipe is connected with a second air suction pipe through a dehumidifying device, one end, far away from the dehumidifying device, of the second air suction pipe is connected with a material selecting fan, and the blowing end of the material selecting fan is positioned on the lower right side of the mesh belt; the inner bottom wall of the drying chamber is equidistantly provided with a plurality of funnel-shaped blanking grooves, the inner wall of each blanking groove is provided with a humidity sensor, the inner bottom of each blanking groove is provided with a solenoid valve, a transition cavity communicated with the plurality of blanking grooves is formed in the furnace body, the inner walls of the two sides of the transition cavity are rotatably connected with spiral material pushing rods, one ends of the spiral material pushing rods penetrate through the transition cavity and are fixedly connected with a third motor, the inner top wall of the transition cavity is communicated with a first backflow pipe, one end of the first backflow pipe penetrates through the furnace body and is connected with a backflow fan, the air outlet end of the backflow fan is connected with a second backflow pipe, and one end, away from the backflow fan, of the second backflow pipe penetrates through the furnace body and extends to; the upper end of furnace body is provided with the doffer, the outside of furnace body is provided with control panel, control panel and humidity transducer, solenoid valve, first motor, third motor, return fan electric connection.

Preferably, the turn-over device includes that two are fixed at the kicking blocks of the interior roof of drying chamber, two a plurality of turn-over shifting blocks of the equal equidistance fixedly connected with of lower extreme of kicking block, and a plurality of turn-over shifting blocks staggered distribution of two kicking block lower extremes.

Preferably, the dehydrating unit includes the dehumidification case of fixed connection in the furnace body outside, the spout has been seted up to the bilateral inner wall symmetry of dehumidification case, sliding connection has the slider in the spout, two the relative one side integrated into one piece of slider has the box body, the inner wall of box body is from last to being provided with first water absorption layer and the second layer that absorbs water down.

Preferably, the sliding groove is a dovetail groove, and the section of the sliding block is a dovetail block.

Preferably, the first water absorption layer is a quicklime layer, the second water absorption layer is a water absorption plate layer, and a plurality of vent holes are uniformly formed in the inner bottom wall of the box body.

Preferably, the doffer includes and installs the blanking ware in the furnace body upper end through the mounting bracket, be equipped with the feeding trough in the blanking ware, the lower extreme sealing connection of feeding trough has the blanking pipe, the lower extreme and the drying chamber intercommunication of blanking pipe, the intraductal level of blanking has the movable plate to sealed sliding connection, the drain hole has been seted up at the middle part of movable plate, the both ends downside of movable plate all is fixed with a plurality of teeth of a cogwheel, and a plurality of teeth of a cogwheel all mesh and be connected with incomplete gear, the upper end fixed mounting of furnace body has two second motors, the output of two second motors respectively with the coaxial fixed connection of two incomplete gears.

Preferably, the driving directions of the two second motors are opposite.

The invention has the following beneficial effects:

1. the air heated in the drying chamber is pumped to a dehumidifying device through a material selecting fan to remove water vapor, and the gynostemma pentaphylla is winnowed by utilizing the dehumidified hot air, so that the resource waste caused by the fact that the hot air directly enters the atmosphere is avoided, and the drying chamber is automatically dehumidified;

2. the humidity sensor is used for monitoring the humidity condition of the gynostemma pentaphylla in the charging chute in real time, and the gynostemma pentaphylla is dried again or directly discharged according to the humidity condition, so that the gynostemma pentaphylla can be processed in real time, and the operation is convenient;

3. in the mesh belt conveying process, the turnover shifting blocks at the lower ends of the two top blocks turn over the gynostemma pentaphylla, so that the contact area of the gynostemma pentaphylla and hot air is increased, and the drying effect is improved;

4. hot air sucked into the dehumidification box through the first water suction pipe sequentially passes through the first water suction layer, the second water suction layer and the vent holes in the box body to enter the second water suction pipe, the quicklime layer can generate certain heat while absorbing water, and in addition, the water suction plate layer can adsorb moisture again to remove water vapor in the hot air, so that the dehumidification box is simple and convenient;

5. the movable plate makes reciprocating linear motion in the horizontal direction, and the gynostemma pentaphylla intermittently falls into the upper end of the mesh belt through the material leakage port, so that the problem of poor drying effect caused by manual feeding and excessive heating of the gynostemma pentaphylla to the upper end of the mesh belt at one time is avoided.

Drawings

Fig. 1 is a structural perspective view of the front surface of an energy-saving gynostemma pentaphylla drying oven provided by the invention.

FIG. 2 is a perspective view of a part of a top view of an energy-saving oven for drying Gynostemma pentaphyllum.

Fig. 3 is a partially enlarged schematic view of fig. 1.

Fig. 4 is an enlarged schematic view of a portion a in fig. 1.

In the figure: 1 furnace body, 2 rotating shafts, 3 belt wheels, 4 synchronous belts, 5 mesh belts, 6 first motors, 7 heating plates, 8 top blocks, 9 turnover shifting blocks, 10 blanking devices, 11 moving plates, 12 second motors, 13 incomplete gears, 14 material leaking ports, 15 blanking pipes, 16 first air suction pipes, 17 dehumidifying devices, 1701 dehumidifying boxes, 1702 sliding grooves, 1703 sliding blocks, 1704 box bodies, 1705 second water suction layers, 1706 first water suction layers, 18 second air suction pipes, 19 material selecting fans, 20 material falling tanks, 21 humidity sensors, 22 electromagnetic valves, 23 transition cavities, 24 spiral material pushing rods, 25 third motors, 26 material discharging ports, 27 first return pipes, 28 return fans, 29 second return pipes and 30 control panels.

Detailed Description

The following examples are for illustrative purposes only and are not intended to limit the scope of the present invention.

Referring to fig. 1-4, an energy-saving gynostemma pentaphylla drying oven comprises an oven body 1, a drying chamber is arranged in the oven body 1, two rotating shafts 2 are rotatably connected to the inner walls of the two sides of the drying chamber, two belt pulleys 3 are fixedly sleeved on the corresponding positions of the two rotating shafts 2, two belt pulleys 3 which are respectively positioned on the two rotating shafts 2 and correspond to the positions are jointly tensioned and sleeved with a synchronous belt 4, a mesh belt 5 is fixedly connected between the two synchronous belts 4, wherein the belt pulleys 3 and the synchronous belts 4 can be replaced by chain wheels and chains, one end of one of the rotating shafts 2 penetrates through the drying chamber and is fixedly connected with a first motor 6, the first motor 6 is a low-speed motor, and the first motor 6 is fixedly arranged on the furnace body 1, the heating plate 7 is arranged on the inner wall of the drying chamber and the inner side of the mesh belt 5, of course, the heating plate 7 is not limited, other heating devices can be adopted, and the inner top wall of the drying chamber is provided with the turnover device;

a first air suction pipe 16 is hermetically communicated with the right side of the mesh belt 5 on the inner top wall of the drying chamber, the first air suction pipe 16 is connected with a second air suction pipe 18 through a dehumidifying device 17, one end, far away from the dehumidifying device 17, of the second air suction pipe 18 is connected with a material selecting fan 19, and the blowing end of the material selecting fan 19 is positioned on the right lower side of the mesh belt 5;

a plurality of funnel-shaped blanking grooves 20 are equidistantly formed in the inner bottom wall of the drying chamber, a humidity sensor 21 is mounted on the inner wall of each blanking groove 20, an electromagnetic valve 22 is mounted at the inner bottom of each blanking groove 20, a transition cavity 23 communicated with the plurality of blanking grooves 20 is formed in the furnace body 1, inner walls on two sides of each transition cavity 23 are rotatably connected with a spiral material pushing rod 24, one end of each spiral material pushing rod 24 penetrates through the transition cavity 23 and is fixedly connected with a third motor 25, a first backflow pipe 27 is communicated with the inner top wall of each transition cavity 23, one end of each first backflow pipe 27 penetrates through the furnace body 1 and is connected with a backflow fan 28, the air outlet end of each backflow fan 28 is connected with a second backflow pipe 29, and one end, far away from the backflow fan 28, of each second backflow pipe 29 penetrates;

the blanking device is arranged at the upper end of the furnace body 1, the control panel 30 is arranged at the outer side of the furnace body 1, and the control panel 30 is electrically connected with the humidity sensor 21, the electromagnetic valve 22, the first motor 6, the third motor 25 and the return fan 28.

It should be noted that, control panel 30 includes the display screen, and the signal of telecommunication that humidity transducer 21 sent is observed to the accessible display screen, makes things convenient for the staff to know the humidity condition of stoving back gynostemma pentaphylla in real time, and the opening and closing of controllable humidity transducer 21 of control panel 30, solenoid valve 22, first motor 6, third motor 25 and return-flow fan 28 simultaneously.

In the invention, a first motor 6 drives one of the rotating shafts 2 to rotate, a second rotating shaft 2 drives a synchronous belt 4 and a mesh belt 5 fixedly connected with the synchronous belt 4 to rotate clockwise through a belt pulley 3, in the process, the gynostemma pentaphylla to be dried uniformly falls to the upper end of the mesh belt 5 through a blanking device, a heating plate 7 heats air so as to dry the gynostemma pentaphylla in transmission through the mesh belt 5, on one hand, a material selecting fan 19 pumps hot air with water vapor in a drying chamber into a dehumidifying device 17 through a first air suction pipe 16, the dehumidified hot air passes through a second air suction pipe 18 and is blown into the drying chamber again by the material selecting fan 19, the gynostemma pentaphylla gradually transmitted to the right end on the mesh belt 5 makes free falling body movement under the action of gravity, but under the influence of the wind power of the material selecting fan 19, the influence degrees of the gynostemma pentaphylla different drying degree are different in the wind power, the lighter (the lower humidity) of the gynostemma pentaphylla can fall into a material falling groove 20 positioned on the left side, the heavier (lower humidity) gynostemma pentaphylla is likely to fall into the charging chute 20 on the right side, the humidity of the gynostemma pentaphylla in the charging chute 20 can be monitored through the humidity sensor 21 and fed back to the control panel 30, a worker can know through the display screen and determine which charging chute 20 needs to be dried again according to actual needs, the gynostemma pentaphylla in which charging chute 20 meets production requirements, specifically, the electromagnetic valve 22, the third motor 25 and the return fan 28 corresponding to the gynostemma pentaphylla needing to be dried again are opened, the third motor 25 drives the spiral material pushing rod 24 to gradually move the gynostemma pentaphylla to the left side, under the action of suction, the gynostemma pentaphylla is sucked into the first return pipe 27 and pumped to the upper end of the left side of the mesh belt 5 through the second return pipe 29 by the return fan 28 to be dried again, the electromagnetic valve 22 and the third motor 25 corresponding to the gynostemma pentaphylla humidity meeting requirements are opened, the third motor 25 drives the spiral material pushing rod 24 to rotate, and the gynostemma pentaphylla flows out through the material outlet 26 under the action of gravity and is used.

According to the invention, the air heated in the drying chamber is pumped to the dehumidifying device 17 by the material selecting fan 19 to remove water vapor, and the gynostemma pentaphylla is winnowed by using the dehumidified hot air, so that the resource waste caused by the fact that the hot air directly enters the atmosphere is avoided, and the dehumidifying operation is automatically carried out on the drying chamber; utilize humidity transducer 21 real-time supervision charging conduit 20 in the humidity condition of gynostemma pentaphylla to carry out stoving once more or direct blanking to gynostemma pentaphylla according to the humidity condition, can handle convenient operation in real time to gynostemma pentaphylla.

The turn-over device comprises two top blocks 8 fixed on the top wall in the drying chamber, a plurality of turn-over shifting blocks 9 fixedly connected with the lower ends of the two top blocks 8 at equal intervals, and the turn-over shifting blocks 9 at the lower ends of the two top blocks 8 are distributed in a staggered mode.

In the invention, in the conveying process of the mesh belt 5, the turning-over shifting blocks 9 at the lower ends of the two top blocks 8 turn over the gynostemma pentaphylla, so that the contact area of the gynostemma pentaphylla and hot air is increased, and the drying effect is improved.

Dehumidification device 17 includes the dehumidification case 1701 of fixed connection in the furnace body 1 outside, spout 1702 has been seted up to dehumidification case 1701's both sides inner wall symmetry, sliding connection has slider 1703 in the spout 1702, two slider 1703 relative one side integrated into one piece have box body 1704, the inner wall of box body 1704 is from last to being provided with first water absorption layer 1706 and second water absorption layer 1705 down, spout 1702 is the dovetail, slider 1703's cross-section is the forked tail piece, first water absorption layer 1706 is the lime layer, the second water absorption layer 1705 is the water absorption sheet layer, a plurality of air vents have evenly been seted up to the interior diapire of box body 1704.

In the invention, hot air sucked into the dehumidifying box 1701 through the first water suction pipe 16 sequentially passes through the first water suction layer 1706, the second water suction layer 1705 and the vent holes on the box body 1704 to enter the second water suction pipe 18, the quicklime layer can generate certain heat while absorbing water, and in addition, the water suction plate layer can absorb water again to remove water vapor in the hot air, so that the method is simple and convenient; after a period of use, the box body 1704 can be pulled out to replace the first water absorption layer 1706 and the second water absorption layer 1705, so that the slider 1703 and the sliding groove 1702 can slide and be clamped conveniently.

The blanking device comprises a blanking device 10 installed on the upper end of a furnace body 1 through an installation frame, a feeding trough is arranged in the blanking device 10, a blanking pipe 15 is connected to the lower end of the feeding trough in a sealing mode, the lower end of the blanking pipe 15 is communicated with a drying chamber, a movable plate 11 is connected to the blanking pipe 15 in a horizontal direction in a sealing sliding mode, a material leakage port 14 is formed in the middle of the movable plate 11, a plurality of gear teeth are fixed to the lower sides of the two ends of the movable plate 11, the gear teeth are connected with incomplete gears 13 in an all-meshed mode, two second motors 12 are fixedly installed on the upper end of the furnace body 1, the driving directions of the two second motors 12 are opposite, and the output ends.

In the invention, the driving directions of the two second motors 12 are opposite, when one of the two incomplete gears 13 is in a state of being meshed with a plurality of gear teeth, the other is in a state of not being meshed with the plurality of gear teeth, and the moving plate 11 performs reciprocating linear motion in the horizontal direction as a whole, so that the gynostemma pentaphylla intermittently falls into the upper end of the mesh belt 5 through the material leakage port 14, thereby avoiding the problem of poor drying effect caused by manual feeding and excessive heating of the gynostemma pentaphylla to the upper end of the mesh belt 5 at one time.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. An energy-saving gynostemma pentaphylla drying furnace comprises a furnace body (1) and is characterized in that a drying chamber is arranged in the furnace body (1), two rotating shafts (2) are rotatably connected to inner walls of two sides of the drying chamber, two belt pulleys (3) are fixedly sleeved on corresponding positions of the two rotating shafts (2), two belt pulleys (3) which are respectively positioned on the two rotating shafts (2) and correspond to the rotating shafts are jointly tensioned and sleeved with synchronous belts (4), a mesh belt (5) is fixedly connected between the two synchronous belts (4), one end of one rotating shaft (2) penetrates through the drying chamber and is fixedly connected with a first motor (6), the first motor (6) is fixedly installed on the furnace body (1), a heating plate (7) is installed on the inner wall of the drying chamber and on the inner side of the mesh belt (5), and a turn-over device is arranged in the top wall of the drying chamber;

a first air suction pipe (16) is hermetically communicated with the inner top wall of the drying chamber and the right side of the mesh belt (5), the first air suction pipe (16) is connected with a second air suction pipe (18) through a dehumidifying device (17), one end, far away from the dehumidifying device (17), of the second air suction pipe (18) is connected with a material selecting fan (19), and the blowing end of the material selecting fan (19) is located on the lower right side of the mesh belt (5);

a plurality of funnel-shaped charging chutes (20) are arranged on the inner bottom wall of the drying chamber at equal intervals, humidity sensors (21) are arranged on the inner walls of the charging chutes (20), an electromagnetic valve (22) is installed at the inner bottom of the charging chute (20), a transition cavity (23) communicated with the charging chutes (20) is arranged in the furnace body (1), the inner walls of the two sides of the transition cavity (23) are rotationally connected with a spiral material pushing rod (24), one end of the spiral material pushing rod (24) penetrates through the transition cavity (23) and is fixedly connected with a third motor (25), the inner top wall of the transition cavity (23) is communicated with a first return pipe (27), one end of the first return pipe (27) penetrates through the furnace body (1) and is connected with a return fan (28), the air outlet end of the return fan (28) is connected with a second return pipe (29), and one end, far away from the return fan (28), of the second return pipe (29) penetrates through the furnace body (1) and extends to the upper end of the mesh belt (5);

the blanking device is arranged at the upper end of the furnace body (1), a control panel (30) is arranged on the outer side of the furnace body (1), and the control panel (30) is electrically connected with the humidity sensor (21), the electromagnetic valve (22), the first motor (6), the third motor (25) and the return fan (28).

2. The energy-saving gynostemma pentaphylla drying furnace according to claim 1, wherein the turnover device comprises two top blocks (8) fixed on the inner top wall of the drying chamber, a plurality of turnover shifting blocks (9) are fixedly connected to the lower ends of the two top blocks (8) at equal intervals, and the turnover shifting blocks (9) at the lower ends of the two top blocks (8) are distributed in a staggered manner.

3. The energy-saving gynostemma pentaphylla drying oven according to claim 1, wherein the dehumidifying device (17) comprises a dehumidifying box (1701) fixedly connected to the outer side of the oven body (1), sliding grooves (1702) are symmetrically formed in inner walls of two sides of the dehumidifying box (1701), sliding blocks (1703) are connected in the sliding grooves (1702) in a sliding mode, a box body (1704) is integrally formed on one side, opposite to the two sliding blocks (1703), of the box body (1704), and a first water absorbing layer (1706) and a second water absorbing layer (1705) are arranged on the inner walls of the box body (1704) from top to bottom.

4. The energy-saving gynostemma pentaphylla drying oven according to claim 3, wherein the sliding groove (1702) is a dovetail groove, and the section of the sliding block (1703) is a dovetail block.

5. The energy-saving gynostemma pentaphylla drying oven according to claim 3, wherein the first water absorption layer (1706) is a quicklime layer, the second water absorption layer (1705) is a water absorption plate layer, and a plurality of vent holes are uniformly formed in the inner bottom wall of the box body (1704).

6. The energy-saving gynostemma pentaphylla drying furnace according to claim 1, wherein the blanking device comprises a blanking device (10) arranged at the upper end of the furnace body (1) through a mounting rack, a feeding trough is arranged in the blanking device (10), the lower end of the feeding trough is connected with a blanking pipe (15) in a sealing way, the lower end of the blanking pipe (15) is communicated with the drying chamber, a moving plate (11) is connected in the blanking pipe (15) in a sliding manner in the horizontal direction in a sealing manner, a material leakage port (14) is formed in the middle of the moving plate (11), a plurality of gear teeth are fixed on the lower sides of two ends of the moving plate (11), and a plurality of teeth of a cogwheel all be joggled with incomplete gear (13), the upper end fixed mounting of furnace body (1) has two second motors (12), the output of two second motors (12) respectively with two incomplete gear (13) coaxial fixed connection.

7. The energy-saving gynostemma pentaphylla drying oven as claimed in claim 6, wherein the driving directions of the two second motors (12) are opposite.