CN214356788U - Reinforced mechanism and sesame oil packaging production line - Google Patents

Abstract

The utility model discloses a reinforced mechanism, include: the feeding device comprises a rack, and a feeding assembly, a two-stage vibration material distribution assembly, a conveying assembly and a discharging assembly which are sequentially arranged on the rack from top to bottom, wherein the discharging end of the feeding assembly is provided with at least one group of two-stage vibration material distribution assemblies; the two-stage vibration material distribution assembly comprises a direct vibration assembly and a circular vibration assembly which are sequentially arranged, the discharge end of the feeding assembly is connected with the direct vibration assembly, and the discharge end of the circular vibration assembly is connected with the conveying assembly; the material that the material loading subassembly output divides the material subassembly to separate the back through the two-stage vibration, is carried to ejection of compact subassembly by the conveying subassembly, exports after the ejection of compact subassembly is collected. The utility model discloses a reinforced mechanism has compact structure, the principle is simple, divide advantages such as material speed is fast, the count is accurate. And simultaneously, the utility model also discloses an areca packing production line that contains above-mentioned reinforced mechanism has realized taking the jumbo size wrapping bag packing areca of zip fastener to the production efficiency of areca packing has been increased substantially.

Description

Reinforced mechanism and sesame oil packaging production line

Technical Field

The utility model mainly relates to a sesame oil packing technical field especially relates to a reinforced mechanism and sesame oil packaging production line.

Background

Betel nut is native to malaysia, and china is mainly distributed in tropical areas such as Yunnan, Hainan and Taiwan. The tropical region of Asia is cultivated widely. According to data, the betel nut industry in China develops rapidly in recent years, the output value is over 400 hundred million yuan, wherein two provinces of Hunan and Hainan are main markets of the betel nut industry in China, and the market share is over 80 percent. Although the areca is introduced from abroad and is a tropical plant, the areca industry in China basically realizes self-sufficiency, the areca yield in areas such as Hainan and the like can sufficiently meet the domestic requirements, the areca yield in China keeps a stable growth situation in recent years, and the areca yield in China reaches more than 150 million tons in 2018. In recent years, the betel nut industry in China gradually moves to the high-end market along with the development of economy, and from the aspect of market consumption, consumers are more and more inclined to middle-high-end products. Correspondingly, the areca packages tend to be larger and more packed particles. However, the existing betel nut packaging technology is not suitable for packaging large-size and zipper-type packaging bags, and cannot achieve the packaging efficiency required by the large-size packaging bags. The reason is that the existing equipment is not provided with a zipper bag opening mechanism, and cannot be compatible with large-size packaging bags, the packaging stations are few, and the packaging efficiency is low. And the material distributing mechanism in the prior art has the disadvantages of low material distributing speed, uneven material distribution, large occupied area and difficulty in meeting the feeding requirement of packing the areca nuts in large packing bags.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome prior art not enough, provide a compact structure, the principle is simple, divide fast, the accurate reinforced mechanism of count of material, still provide the sesame oil packaging production line that contains this reinforced mechanism simultaneously.

In order to solve the technical problem, the utility model discloses a following technical scheme:

a charging mechanism comprising: the feeding device comprises a rack, and a feeding assembly, a two-stage vibration material distribution assembly, a conveying assembly and a discharging assembly which are sequentially arranged on the rack from top to bottom, wherein the discharging end of the feeding assembly is provided with at least one group of two-stage vibration material distribution assemblies; the two-stage vibration material distribution assembly comprises a direct vibration assembly and a circular vibration assembly which are sequentially arranged, the discharge end of the feeding assembly is connected with the direct vibration assembly, and the discharge end of the circular vibration assembly is connected with the conveying assembly; the material that the material loading subassembly output divides the material subassembly to separate the back through the two-stage vibration, is carried to ejection of compact subassembly by the conveying subassembly, exports after the ejection of compact subassembly is collected.

As a further improvement, the material loading subassembly includes the hopper, the bottom both sides of hopper all are equipped with at least a set of subassembly that directly shakes, there is the clearance between the discharge end of hopper bottom and the subassembly that directly shakes, the clearance is used for leveling the material and making single material pass through.

As a further improvement, the discharge end of the direct vibration assembly and the feed end of the circular vibration assembly are provided with a baffle plate therebetween, and the baffle plate assists the material to fall into the circular vibration assembly from the direct vibration assembly.

As a further improvement, the conveying assembly comprises a conveying belt, the tail end of the conveying belt is provided with a photoelectric sensor, and the quantity of materials is detected through the photoelectric sensor.

As a further improvement, the discharging component comprises a collecting hopper, a blanking channel and a driving component, the blanking channel is arranged at the discharging end of the collecting hopper, and the driving component is used for controlling the opening and closing of the collecting hopper.

As a general technical concept, the utility model also provides an areca nut packaging production line, include: the feeding mechanism, the deoxidizing agent throwing mechanism, the packaging bag supply unit, the charging mechanism, the sealing unit and the discharging unit are arranged on the conveying mechanism; reinforced mechanism is connected with charging mechanism to realize the sesame oil filling, deoxidier input mechanism is connected with wrapping bag supply unit to realize that the deoxidier package is put in, the wrapping bag that is equipped with the deoxidier moves to charging mechanism and carries out the sesame oil filling, and the wrapping bag that accomplishes the sesame oil filling moves to sealing the unit and seals the back through ejection of compact unit output.

As a further improvement of the utility model, the packaging bag supply unit comprises a bag feeding mechanism, a packaging bag opening zipper mechanism and a bag pre-opening mechanism which are arranged in sequence, and the deoxidizer feeding mechanism is connected with the bag pre-opening mechanism to realize the feeding of deoxidizer material bags; the sealing unit comprises a pre-sealing mechanism and a sealing mechanism; go up bag mechanism, open wrapping bag zip fastener mechanism, open bag mechanism, charging mechanism, seal mechanism in advance and seal the mechanism and encircle the annular guide setting in proper order, under actuating mechanism's drive, the wrapping bag flows to corresponding packing station through the annular guide.

As a further improvement of the utility model, go up bag mechanism, open the wrapping bag zip fastener mechanism, open bag mechanism in advance, seal the mechanism in advance and seal the mechanism and all set up two at least to realize a plurality of wrapping bags operation simultaneously.

As a further improvement of the utility model, at least four charging mechanisms are arranged to realize the multiple filling of the betel nuts; every charging mechanism includes two stations of feeding at least to realize that a plurality of wrapping bags are filled the sesame oil simultaneously.

As a further improvement of the utility model, the utility model also comprises a controller, and the human-computer interaction is realized through the controller; the discharging unit comprises a discharging conveying mechanism and a waste collecting box, and the discharging conveying mechanism and the waste collecting box are connected with the sealing mechanism.

Compared with the prior art, the utility model has the advantages of:

1. the utility model discloses a reinforced mechanism, through with the hopper, directly shake subassembly, circle shake subassembly, conveyor belt, collecting hopper and the equal integrated installation of blanking passageway in the frame, have compact structure, the small advantage of installation. The materials in the hopper firstly enter the direct vibration assembly to realize the separation of single materials, then enter the circular vibration assembly from the discharge end of the direct vibration assembly, and further pull open the space between the single materials; through the cooperation of directly shaking and circle shake, can enough provide sufficient separation space, improve the speed and the homogeneity of material separation for the material, reduced the whole installation volume of reinforced mechanism simultaneously again. After the material comes out of the discharge end of the circular vibration assembly, the material is conveyed into a material collecting hopper through a conveying belt and is stored for a short time; the photoelectric counter is arranged at the tail end of the conveying belt, so that materials are counted, after the preset number is reached, the driving assembly (such as an air cylinder) controls the material collecting hopper to be opened, the materials fall into the blanking channel, and feeding is completed; the accuracy of material counting is improved, the automation level of the feeding mechanism is improved, and the working efficiency is improved.

2. The utility model discloses a betel nut packaging production line through will go up bag mechanism, open wrapping bag zip fastener mechanism, open bag mechanism in advance, seal the mechanism in advance and seal the mechanism and all set up two in succession, has realized the operation when two wrapping bags. Meanwhile, four filling mechanisms are continuously arranged, four times of filling of materials are achieved, two filling stations are arranged on the filling mechanisms, the two packaging bags are filled with the materials at the same time, and the filling efficiency of the materials is greatly improved. Under the drive of the servo motor, the packaging bags are operated to corresponding packaging stations through the annular guide rails so as to perform corresponding packaging operation. The whole packaging production line has the advantages of high automation degree, high packaging efficiency, high finished product qualification rate and the like, and realizes the packaging of the betel nuts by large-size packaging bags with the width of 128-180 mm and the length of 178-240 mm.

Drawings

Fig. 1 is a schematic view of the structural principle of the feeding mechanism of the present invention.

Fig. 2 is one of the schematic structural diagrams of the betel nut packaging production line of the present invention.

Fig. 3 is a second schematic structural diagram of the betel nut packaging production line of the present invention.

Fig. 4 is a third schematic view of the structural principle of the betel nut packaging production line of the present invention.

Fig. 5 is a schematic diagram of the station arrangement principle of the packing machine frame in the betel nut packing production line of the utility model.

Illustration of the drawings:

1. a feeding mechanism; 101. a hopper; 102. a direct vibration component; 103. a circular vibration assembly; 104. a conveyor belt; 105. a collection hopper; 106. a blanking channel; 107. a drive assembly; 2. a deoxidizer feeding mechanism; 3. a bag feeding mechanism; 4. opening a zipper mechanism of the packaging bag; 5. a controller; 6. a bag pre-opening mechanism; 7. a charging mechanism; 8. a pre-sealing mechanism; 9. a sealing mechanism; 10. an annular guide rail; 11. a discharge conveying mechanism; 12. a waste collection box; 13. a frame; 131. mounting a plate; 132. a support pillar; 133. a support; 14. a baffle plate; A. a support platform; B. and (4) a packaging rack.

Detailed Description

The invention will be further described with reference to the drawings and specific preferred embodiments without limiting the scope of the invention.

Examples

The utility model discloses a feeding mechanism, include: the vibration material distribution device comprises a frame 13, and a feeding assembly, a two-stage vibration material distribution assembly, a conveying assembly and a discharging assembly which are sequentially arranged on the frame 13 from top to bottom, wherein the discharging end of the feeding assembly is provided with at least one group of two-stage vibration material distribution assembly. The two-stage vibration material distribution assembly comprises a direct vibration assembly 102 and a circular vibration assembly 103 which are sequentially arranged, the discharge end of the feeding assembly is connected with the direct vibration assembly 102, and the discharge end of the circular vibration assembly 103 is connected with the conveying assembly. Specifically, as shown in fig. 1, the feeding mechanism of this embodiment includes: the hopper 101, the straight vibration assembly 102, the circular vibration assembly 103, the conveying belt 104, the collecting hopper 105 and the blanking channel 106 are arranged on the frame 13 from top to bottom in sequence. Both sides of the bottom of the hopper 101 are provided with the direct vibration assemblies 102, and a gap is formed between the discharge end of the bottom of the hopper 101 and the direct vibration assemblies 102 and used for leveling materials and enabling single materials to pass through. The discharge end of the direct vibration component 102 is provided with a circular vibration component 103, the circular vibration component 103 and the direct vibration component 102 are in one-to-one correspondence, the discharge end of the circular vibration component 103 is connected with the front end of a conveying belt 104, the tail end of the conveying belt 104 is provided with a material collecting hopper 105, and the discharge end of the material collecting hopper 105 is connected with a blanking channel 106. It can be understood that two or three straight vibrating assemblies 102 can be arranged side by side on both sides of the bottom of the hopper 101 according to actual production requirements, and the number of the circular vibrating assemblies 103 is matched with that of the straight vibrating assemblies 102. The plurality of direct vibration assemblies 102 are arranged at the bottom of the hopper 101, so that more material distribution channels are provided, and the material separation speed is improved.

Further, in the present embodiment, the rack 13 includes a mounting plate 131, a bracket 133 and a supporting column 132, the hopper 101 and the straight vibration assembly 102 are both mounted on the top of the rack 13, and the circular vibration assembly 103 is mounted on the mounting plate 131; the conveying belt 104, the collecting hopper 105 and the blanking channel 106 are all mounted on a bracket 133, and the bracket 133 is connected with the supporting column 132. It can be understood that the bottom of the mounting plate 131 can be provided with a roller assembly to improve the moving convenience of the circular vibration assembly 103, and also facilitate the adjustment of the position between the circular vibration assembly 103 and the straight vibration assembly 102, thereby improving the blanking accuracy.

Further, in this embodiment, a baffle 14 is disposed between the discharge end of the direct vibration assembly 102 and the circular vibration assembly 103, and the baffle 14 assists the material to fall into the circular vibration assembly 103 from the direct vibration assembly 102. It is understood that the direct vibration assembly 102 includes a direct vibration flow path and a direct vibration generator for vibrating the direct vibration flow path, and the circular vibration assembly 103 includes a circular vibration plate and a circular vibration generator for vibrating the circular vibration plate. The materials coming out of the hopper 101 are separated by the straight vibration flow channel and then enter the circular vibration disc in sequence. Utilize baffle 14 to assist the water conservancy diversion to the material, avoid the material to shake the in-process that the export falls into the circle from directly shaking and shake the dish and drop to the circle and shake the dish outside. Meanwhile, the baffle plate 14 can also play a role in positioning, so that materials can accurately fall into the material flow channel of the circular vibration plate, and the separation efficiency of the materials is improved.

In this embodiment, in order to improve the automation degree of feeding, the end of conveyor belt 104 is equipped with photoelectric sensor, detects the quantity of material through photoelectric sensor. The charging mechanism 1 further comprises a driving assembly 107, and the opening and closing of the collection hopper 105 are controlled through the driving assembly 107. A drive assembly 107 is also provided on the carriage 133 and is connected to the collection hopper 105. It is understood that the driving assembly 107 may be specifically a cylinder, and may also be another driving structure as long as the opening and closing of the collection hopper 105 can be controlled. Two collection hoppers 105 are mounted side by side on top of the blanking channel 106. It can be understood that in the feeding mechanism 1, the straight vibration component 102, the circular vibration component 103, the conveying belt 104 and the collecting hopper 105 form a material distribution unit, and two material distribution units symmetrically arranged on two sides of the frame 13 share one blanking channel 106, which not only improves the material distribution efficiency, but also reduces the overall installation volume of the feeding mechanism 1. When one material distribution unit breaks down, the other material distribution unit can still be used for feeding materials, so that the working efficiency and the feeding stability of the feeding mechanism 1 are effectively improved.

In this embodiment, the hopper 101, the straight vibration assembly 102, the circular vibration assembly 103, the conveying belt 104, the collecting hopper 105 and the blanking channel 106 are integrally mounted on the frame 13, so that the feeding device has the advantages of compact structure and small mounting volume. The materials in the hopper 101 firstly enter the direct vibration component 102 to realize the separation of single materials, and then enter the circular vibration component 103 from the discharge end of the direct vibration component 102 to further pull the distance between the single materials; through the cooperation of directly shaking and circle shake, can enough provide sufficient separation space, improve the speed and the homogeneity of material separation for the material, reduced the whole installation volume of reinforced mechanism 1 again simultaneously. After coming out from the discharge end of the circular vibration assembly 103, the materials are conveyed into a material collecting hopper 105 through a conveying belt 104 and are stored for a short time; the photoelectric counter is arranged at the tail end of the conveying belt 104 to count materials, after the preset number is reached, the driving assembly 107 controls the collecting hopper 105 to be opened, the materials fall into the blanking channel 106, and feeding is completed; the accuracy of material counting is improved, the automation level of the feeding mechanism is improved, and the working efficiency is improved.

As shown in fig. 2 to 4, the present embodiment further provides an areca nut packaging production line, which includes the above-mentioned feeding mechanism 1, and a deoxidizer throwing mechanism 2, a packaging bag supplying unit, a charging mechanism 7, a sealing unit and a discharging unit. The feeding mechanism 1 is connected with the charging mechanism 7 to realize betel nut filling, the deoxidizing agent throwing mechanism 2 is connected with the packaging bag supply unit to realize deoxidizing agent package throwing, the packaging bag filled with the deoxidizing agent runs to the charging mechanism 7 to carry out betel nut filling, and the packaging bag filled with the betel nuts runs to the sealing unit to be sealed and then is output through the discharging unit. Specifically, the sesame oil packaging production line of this embodiment includes: supporting platform A and packing frame B, supporting platform A is located packing frame B top. The support platform A is provided with a deoxidizer throwing mechanism 2 and the feeding mechanism 1. The packaging machine frame B is provided with an annular guide rail 10, and a bag feeding mechanism 3, a bag opening zipper mechanism 4, a bag pre-opening mechanism 6, a loading mechanism 7, a pre-sealing mechanism 8 and a sealing mechanism 9 which are sequentially arranged around the annular guide rail 10, wherein under the driving of the driving mechanism, the packaging bags flow to corresponding packaging stations through the annular guide rail 10. In this embodiment, the bags are moved on the endless track 10 to the respective packaging stations under the control of the servo motor. The feeding mechanism 1 is connected with the charging mechanism 7 to realize the filling of the betel nuts; the deoxidizer feeding mechanism 2 is connected with the bag pre-opening mechanism 6 so as to realize the feeding of the deoxidizer material bag. It can be understood that deoxidier input mechanism 2 can adopt the circle to shake reinforced mechanism and throw the material, is equipped with the blanking passageway on the deoxidier input mechanism 2, and the deoxidier material package falls into the wrapping bag of opening the mouth on opening bag mechanism 6 in advance through the blanking passageway, and the wrapping bag that is equipped with the deoxidier material package continues to operate to charging mechanism 7, loads.

Further, in this embodiment, the feeding mechanism 1 is connected to the supporting platform a through the mounting plate 131 and the supporting column 132, the blanking channel 106 of the feeding mechanism 1 passes through the supporting platform a to be connected to the charging mechanism 7, and the blanking channel 106 corresponds to the charging mechanism 7 one by one. The material falls into the packaging bag with an opening on the loading mechanism 7 through the blanking channel 106. As shown in fig. 4, in the present embodiment, four charging mechanisms 7 are provided in series, and four times of filling of betel nuts are realized by the four charging mechanisms 7; each filling mechanism 7 comprises two filling stations to enable two packages to be filled with material at the same time. By adopting the mode of four times of filling, the stability and the uniformity of the filling material are improved, and the speed of the filling material is also improved. Correspondingly, in this embodiment, the bag feeding mechanism 3, the bag opening zipper mechanism 4, the bag pre-opening mechanism 6, the pre-sealing mechanism 8 and the sealing mechanism 9 are continuously arranged in two, so as to realize the simultaneous operation of two bags.

In this embodiment, the device further comprises a controller 5, an output conveying mechanism 11 and a waste collecting box 12. Human-computer interaction is realized through the controller 5, the running state of the whole production line is controlled, the automation degree of the betel nut packaging production line is improved, and meanwhile, the production cost is effectively reduced. The discharging and conveying mechanism 11 and the waste collecting box 12 are both connected with the sealing mechanism 9, the qualified products can be conveyed to the next production procedure from the discharging and conveying mechanism 11, and the unqualified products can be collected in the waste collecting box 12 for corresponding treatment.

Further, fig. 5 shows a schematic layout of stations on the packaging machine frame in the betel nut packaging production line of the present embodiment. In fig. 5, (1) and (2) show bag-feeding stations, which are start stations of the entire production line. The packaging bags at the bag feeding station are operated to the bag zipper opening stations (3) and (4) through the annular guide rail 10, and the zipper opening of the packaging bags is realized at the stations (3) and (4). The zipper-opened packaging bag continuously runs to the bag opening pre-opening stations (5) and (6) through the annular guide rail 10, and the primary opening of the packaging bag is realized at the stations (5) and (6). Meanwhile, the deoxidizer feeding mechanism 2 feeds the deoxidizer material bag into the opened packaging bag. The packaging bags filled with the deoxidizer bags continue to move to a loading station through the annular guide rail 10 for loading the betel nuts, the station (7) to the station (14) represent loading stations, and the two packaging bags filled with the deoxidizer bags are loaded for four times under the corresponding packaging stations respectively. The packaging bags filled with materials are continuously operated to pre-sealing stations (15) and (16) through the annular guide rail 10 to be pre-sealed, and the bag mouths of the packaging bags are leveled and aligned through the pre-sealing stations to be pre-sealed. The bag, once pre-sealed, continues to travel through the endless track 10 to the sealing stations (17) and (18) for final sealing. After the sealing is finished, the qualified products are output through the discharging and conveying mechanism 11, and the unqualified products are collected in the waste product collecting box 12. In the sesame oil packaging production line of this embodiment, through increasing the station, realize that two wrapping bags feed simultaneously, improved the packing efficiency of sesame oil greatly. Through setting up the packing bag zip fastener station of opening and the packing bag station of opening, realized opening of the jumbo size wrapping bag of taking the zip fastener, satisfied the demand of jumbo size wrapping bag packing sesame oil. The packaging bag is sealed twice by arranging the pre-sealing station and the sealing station, so that the sealing quality of the packaging bag is effectively improved, and the packaging qualified rate is improved.

In this embodiment, two bag feeding mechanisms 3, two bag opening zipper mechanisms 4, two bag pre-opening mechanisms 6, two bag pre-sealing mechanisms 8 and two bag sealing mechanisms 9 are continuously arranged, so that the two bags can be simultaneously operated. Meanwhile, four filling mechanisms 7 are continuously arranged, four times of filling of materials are achieved, two filling stations are arranged on the filling mechanisms 7, the two packaging bags are filled with the materials at the same time, and the filling efficiency of the materials is greatly improved. Under the drive of the servo motor, the packaging bags are operated to the corresponding packaging stations through the annular guide rail 10 so as to carry out the corresponding packaging operation. The whole packaging production line has the advantages of high automation degree, high packaging efficiency, high finished product qualification rate and the like, and realizes the packaging of the betel nuts by large-size packaging bags with the width of 128-180 mm and the length of 178-240 mm.

Although the present invention has been described with reference to the preferred embodiments, it is not intended to limit the present invention. Those skilled in the art can make numerous changes and modifications to the disclosed embodiments, or modify equivalent embodiments, without departing from the spirit and scope of the invention, using the methods and techniques disclosed above. Therefore, any simple modification, equivalent replacement, equivalent change and modification made to the above embodiments by the technical entity of the present invention all still belong to the protection scope of the technical solution of the present invention.

Claims (10)

1. A charging mechanism, comprising: the feeding device comprises a rack (13), and a feeding assembly, a two-stage vibration material distribution assembly, a conveying assembly and a discharging assembly which are sequentially arranged on the rack (13) from top to bottom, wherein the discharging end of the feeding assembly is provided with at least one group of two-stage vibration material distribution assembly; the two-stage vibration material distribution assembly comprises a direct vibration assembly (102) and a circular vibration assembly (103) which are sequentially arranged, the discharge end of the feeding assembly is connected with the direct vibration assembly (102), and the discharge end of the circular vibration assembly (103) is connected with the conveying assembly; the material that the material loading subassembly output divides the material subassembly to separate the back through the two-stage vibration, is carried to ejection of compact subassembly by the conveying subassembly, exports after the ejection of compact subassembly is collected.

2. The charging mechanism according to claim 1, characterized in that the charging assembly comprises a hopper (101), at least one set of straight vibrating assemblies (102) is arranged on both sides of the bottom of the hopper (101), and a gap exists between the discharging end of the bottom of the hopper (101) and the straight vibrating assemblies (102), and the gap is used for leveling materials and enabling single materials to pass through.

3. The charging mechanism according to claim 2, characterized in that a baffle (14) is arranged between the discharge end of the direct vibration assembly (102) and the feed end of the circular vibration assembly (103), and the baffle (14) is used for assisting the material to fall into the circular vibration assembly (103) from the direct vibration assembly (102).

4. The charging mechanism according to any one of claims 1 to 3, characterized in that said conveying assembly comprises a conveyor belt (104), the end of said conveyor belt (104) being provided with a photoelectric sensor by means of which the quantity of material is detected.

5. The charging mechanism according to any one of claims 1 to 3, characterized in that said outfeed assembly comprises a collection hopper (105), a blanking channel (106) and a drive assembly (107), said blanking channel (106) being located at the outfeed end of the collection hopper (105), said drive assembly (107) being adapted to control the opening and closing of the collection hopper (105).

6. A betel nut packaging production line is characterized by comprising: the charging mechanism (1) according to any one of claims 1 to 5, and a deoxidizer dosing mechanism (2), a packaging bag supply unit, a charging mechanism (7), a sealing unit and a discharging unit; reinforced mechanism (1) is connected with charging mechanism (7) to realize the sesame oil filling, deoxidier input mechanism (2) are connected with wrapping bag supply unit to realize that deoxidier material package puts in, the wrapping bag that is equipped with the deoxidier moves to charging mechanism (7) and carries out the sesame oil filling, and the wrapping bag of accomplishing the sesame oil filling moves to sealing the unit and seals the back and export through ejection of compact unit.

7. The betel nut packaging production line according to claim 6, wherein the packaging bag supplying unit comprises a bag feeding mechanism (3), a packaging bag opening zipper mechanism (4) and a bag pre-opening mechanism (6) which are arranged in sequence, and the deoxidizer throwing mechanism (2) is connected with the bag pre-opening mechanism (6) to realize the throwing of deoxidizer material bags; the sealing unit comprises a pre-sealing mechanism (8) and a sealing mechanism (9); go up bag mechanism (3), open wrapping bag zip fastener mechanism (4), open bag mechanism (6), charging mechanism (7) in advance, seal mechanism (8) in advance and seal mechanism (9) and encircle ring rail (10) setting in proper order, under actuating mechanism's drive, the wrapping bag flows to corresponding packing station through ring rail (10).

8. The betel nut packaging production line according to claim 7, wherein at least two of the bag feeding mechanism (3), the bag opening zipper mechanism (4), the bag pre-opening mechanism (6), the pre-sealing mechanism (8) and the sealing mechanism (9) are arranged so as to realize the simultaneous operation of a plurality of packaging bags.

9. The line according to claim 7, characterized in that said loading means (7) are provided with at least four to allow multiple filling of the areca nuts; each charging mechanism (7) at least comprises two charging stations so as to realize the simultaneous filling of the betel nuts in a plurality of packaging bags.

10. The areca nut packaging production line according to any one of claims 7 to 9, further comprising a controller (5) for realizing human-computer interaction through the controller (5); the discharging unit comprises a discharging conveying mechanism (11) and a waste collecting box (12), and the discharging conveying mechanism (11) and the waste collecting box (12) are connected with the sealing mechanism (9).

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