A packing device for camellia oleifera production and a method of using the same
By designing automated lifting and ejection components, the problem of initial tea cakes being easily broken when manually removed was solved, realizing a highly efficient and automated packaging process for camellia oil production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Filing Date
- 2026-05-23
- Publication Date
- 2026-07-14
AI Technical Summary
In the current camellia oil production process, the initial tea cake is easily broken when it is manually removed, which affects subsequent processing, and the packaging device is inefficient.
Design a packaging device that includes a lifting component, a transmission component, and an ejection component to mechanically eject the initial camellia oil cake from the mold, avoiding manual operation and achieving automated pressing and removal.
This improved material collection efficiency, prevented the initial tea cake from breaking, ensured the smooth progress of subsequent processing, and enhanced overall processing efficiency.
Smart Images

Figure CN122379082A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of camellia oil processing technology, and in particular to a packaging device for camellia oil production and its usage method. Background Technology
[0002] Camellia oleifera is a unique woody edible oil tree species in my country. The tea oil extracted from its fruit is rich in unsaturated fatty acids and has high nutritional value and health benefits.
[0003] The production and processing of camellia oil generally involves multiple steps, including shelling, drying, crushing, steaming and roasting, pressing, and pressing. Before pressing, the steamed and roasted camellia seeds need to be pressed into cakes for packaging to facilitate subsequent pressing. Currently, the packaging equipment for camellia oil forms initial tea cakes after the steamed and roasted seeds are pressed into cakes. These initial tea cakes need to be manually removed from the mold. However, because the initial tea cakes are relatively loose, forcibly removing them manually can easily cause them to break, thus affecting subsequent processing. Therefore, a packaging device for camellia oil production needs to be designed. Summary of the Invention
[0004] In order to overcome the shortcomings of the prior art, the purpose of this invention is to provide a packaging device for camellia oil production and a method of using it.
[0005] The technical solution adopted in this invention is as follows: a packaging device for camellia oil production, comprising a workbench, a first moving mechanism provided at the upper end of the workbench, camellia oil cake molds provided on both sides of the upper end of the first moving mechanism, an ejection component provided inside the camellia oil cake mold for ejecting the initial camellia oil cake from the mold; a support frame fixedly connected to the upper end of the workbench, a storage tank fixedly connected inside the front end of the support frame for storing steamed and roasted camellia oil seeds, a conveying mechanism provided inside the storage tank for conveying the steamed and roasted camellia oil seeds out; and a discharge device fixedly connected to the lower end of the storage tank. The discharge cylinder has a guide cylinder slidably connected to its exterior, and a sealing component is installed inside the discharge cylinder to seal it. A second moving mechanism is installed at the front end of the support frame to drive the guide cylinder to move up and down. Two pressing mechanisms are installed at the upper end of the worktable, located on both sides of the support frame. The pressing mechanisms are used to press the steamed and roasted camellia seeds in the camellia cake mold into initial camellia cakes. A lifting component and a transmission component are installed at the lower end of the worktable. The lifting component, through the transmission component, drives the ejection component to eject the initial camellia cake from the camellia cake mold.
[0006] As a further description of the above technical solution:
[0007] The first moving mechanism includes a moving plate, a first motor, a first bearing seat, a first threaded rod, and a moving block. The first motor and the first bearing seat are fixedly connected to the upper end of the worktable. The first threaded rod is rotatably connected inside the first bearing seat. The output end of the first motor is fixedly connected to the first threaded rod. The moving block is threadedly connected to the first threaded rod. The moving plate is fixedly connected to the upper end of the moving block. The upper end of the moving plate is fixedly connected to the camellia cake mold. Slider blocks are fixedly connected to both the front and rear sides of the lower end of the moving plate. A first slide rail is fixedly connected to the upper end of the worktable. The first slide rail and the slider are slidably connected.
[0008] As a further description of the above technical solution:
[0009] The second moving mechanism includes a second bearing seat, a fourth motor, a moving arm, a third threaded rod, and a second slide rail. The fourth motor, the second slide rail, and the second bearing seat are fixedly connected to the front end of the support frame. The third threaded rod is rotatably connected inside the second bearing seat. The output end of the fourth motor is fixedly connected to the third threaded rod. The moving arm is threadedly connected to the third threaded rod. The moving arm is fixedly connected to the guide cylinder and slidably connected to the second slide rail.
[0010] As a further description of the above technical solution:
[0011] The sealing assembly includes a sealing seat, a sealing ball, and a fixing frame. The sealing seat is fixedly connected inside the discharge cylinder; the fixing frame is fixedly connected inside the guide cylinder, and a sealing ball is fixedly connected to the upper end of the fixing frame. The sealing ball cooperates with the sealing seat.
[0012] As a further description of the above technical solution:
[0013] The material conveying mechanism includes a third motor, a rotating shaft, and auger blades. The rotating shaft is rotatably connected inside the storage tank, and the auger blades are fixedly connected to the rotating shaft. The third motor is fixedly connected to the upper end of the storage tank, and the output end of the third motor is fixedly connected to the rotating shaft.
[0014] As a further description of the above technical solution:
[0015] The pressing mechanism includes a support column, a second motor, a second threaded rod, an L-shaped cantilever, and a pressure plate. The upper end of the worktable is fixedly connected to the support column, and the second threaded rod is rotatably connected inside the support column. The L-shaped cantilever is threadedly connected to the second threaded rod, and the L-shaped cantilever is slidably connected to the support column. The end of the L-shaped cantilever away from the second threaded rod is fixedly connected to the pressure plate. The upper end of the support column is fixedly connected to the second motor, and the output end of the second motor is fixedly connected to the second threaded rod.
[0016] As a further description of the above technical solution:
[0017] The lifting assembly includes a movable frame, a screw, a lifting plate, a guide rod, and a handle. The movable frame is located at the lower end of the worktable, and its upper end extends through the worktable and is slidably connected to it. The movable frame is fixedly connected to the L-shaped cantilever. A screw is threadedly connected to the lower end of the movable frame, and a lifting plate is rotatably connected to the upper end of the screw. A handle is fixedly connected to the lower end of the screw. A guide rod is fixedly connected to the lower end of the lifting plate, and its lower end extends through the movable frame and is slidably connected to it.
[0018] As a further description of the above technical solution:
[0019] The transmission assembly includes a U-shaped frame, a spring, and a baffle. The U-shaped frame is slidably connected inside the worktable, with the upper end of the U-shaped frame passing through the worktable. The baffle is fixedly connected to the upper end of the U-shaped frame. A spring is fixedly connected to the U-shaped frame, and the upper end of the spring is fixedly connected to the worktable.
[0020] As a further description of the above technical solution:
[0021] The ejection assembly includes a lifting rod, a lifting plate, and a mating plate. The lifting rod is slidably connected inside the movable plate. The lifting plate is fixedly connected to the upper end of the lifting rod. The lifting plate is slidably connected to the tea cake mold. The mating plate is fixedly connected to the lower end of the lifting rod. The mating plate corresponds to the baffle.
[0022] A method of using a packaging device for camellia oil production, utilizing the aforementioned packaging device for camellia oil production, includes the following steps:
[0023] S1: Pour the steamed and roasted camellia seeds into the storage bucket, and place the steel hoop and wrapping bag into the camellia cake mold;
[0024] S2: The first moving mechanism drives the camellia cake mold to move, so that one of the camellia cake molds reaches the lower end of the guide cylinder;
[0025] S3: After the tea cake mold reaches the lower end of the guide cylinder, the second moving mechanism works to drive the guide cylinder to move down and open the sealing component;
[0026] S4: After the sealing component is opened, the feeding mechanism works to transport the steamed and roasted camellia seeds inside the storage tank into the camellia cake mold to achieve the purpose of feeding;
[0027] S5: After the material is loaded into the camellia cake mold, the first moving mechanism works in reverse, driving the camellia cake mold to the lower end of the pressing mechanism. With the cooperation of the pressing mechanism, the raw materials inside the camellia cake mold are pressed and packaged into the initial camellia cake.
[0028] S6: After the initial camellia cake is pressed, the pressing mechanism reverses its operation, so that the pressing plate no longer presses the initial camellia cake, and at the same time, it drives the lifting component to move upward. After the lifting component contacts the transmission component, it also drives the transmission component to move upward. As the transmission component moves upward, after the transmission component contacts the ejection component, it pushes the ejection component upward. With the cooperation of the ejection component, the initial camellia cake is ejected from the camellia cake mold.
[0029] The present invention has the following beneficial effects:
[0030] 1. This invention, by setting up a lifting component, a transmission component, and an ejection component, can drive the lifting component to rise together when the pressing mechanism is performing the lifting operation. When the lifting component rises, it will push the transmission component to move upward, which in turn will push the ejection component to move upward, directly ejecting the pressed initial camellia cake from the camellia cake mold. There is no need for manual removal, which not only improves the efficiency of material handling, but also avoids the breakage of the loose initial camellia cake caused by improper force during manual material handling, ensuring the smooth progress of subsequent processing.
[0031] 2. By setting up a first moving mechanism and a camellia cake mold, the present invention enables the equipment to alternately complete the feeding and pressing operations during operation, which greatly improves the overall processing efficiency of packaging and pressing camellia cakes. Attached Figure Description
[0032] Figure 1 This is a schematic diagram of the overall structure of the present invention from a first-view perspective;
[0033] Figure 2 This is a schematic diagram of the overall structure of the invention from a second perspective;
[0034] Figure 3 For the present invention Figure 2 Enlarged view of section A in the middle;
[0035] Figure 4 This is a schematic diagram of the overall structure of the invention from a third-person perspective;
[0036] Figure 5 This is a schematic diagram of the internal structure of the present invention;
[0037] Figure 6 For the present invention Figure 5 Enlarged view of section B;
[0038] Figure 7 For the present invention Figure 5 Enlarged view of section C;
[0039] Figure 8 For the present invention Figure 5 Enlarged view of section D in the middle.
[0040] Legend:
[0041] 1. Workbench; 2. First moving mechanism; 201. Moving plate; 202. First motor; 203. First bearing seat; 204. First threaded rod; 205. Moving block; 3. Camellia cake mold; 4. First slide rail; 5. Slider; 6. Pressing mechanism; 601. Support column; 602. Second motor; 603. Second threaded rod; 604. L-shaped cantilever; 605. Pressure plate; 7. Storage tank; 8. Conveying mechanism; 801. Third motor; 802. Rotating shaft; 803. Screwdriver blade; 9. Second moving mechanism; 901. Second bearing seat; 902. First... Four motors; 903, moving arm; 904, third threaded rod; 905, second slide rail; 10, guide cylinder; 11, support frame; 12, discharge cylinder; 13, lifting assembly; 1301, moving frame; 1302, screw; 1303, lifting plate; 1304, guide rod; 1305, handle; 14, transmission assembly; 1401, U-shaped frame; 1402, spring; 1403, baffle; 15, ejection assembly; 1501, lifting rod; 1502, lifting plate; 1503, mating plate; 16, sealing seat; 17, sealing ball; 18, fixed frame. Detailed Implementation
[0042] Reference Figure 1-8 The present invention provides a packaging device for camellia oil production, comprising a workbench 1, a first moving mechanism 2 disposed on the upper end of the workbench 1, and camellia oil cake molds 3 disposed on both sides of the upper end of the first moving mechanism 2. An ejection component 15 is disposed inside the camellia oil cake mold 3 for ejecting the initial camellia oil cake from the mold 3. A support frame 11 is fixedly connected to the upper end of the workbench 1, and a storage tank 7 is fixedly connected to the front end of the support frame 11 for storing steamed and roasted camellia oil seeds. A conveying mechanism 8 is disposed inside the storage tank 7 for conveying the steamed and roasted camellia oil seeds. A discharge cylinder 12 is fixedly connected to the lower end of the storage tank 7. An external sliding connection is provided with a guide cylinder 10, and a sealing component is provided inside the discharge cylinder 12 to seal the discharge cylinder 12; a second moving mechanism 9 is provided at the front end of the support frame 11 to drive the guide cylinder 10 to move up and down; a pressing mechanism 6 is provided at the upper end of the worktable 1, and there are two pressing mechanisms 6 located on both sides of the support frame 11. The pressing mechanism 6 is used to press the steamed and roasted camellia seeds in the camellia cake mold 3 into an initial camellia cake; a lifting component 13 and a transmission component 14 are provided at the lower end of the worktable 1. The lifting component 13 is used to drive the ejection component 15 to eject the initial camellia cake in the camellia cake mold 3 through the transmission component 14.
[0043] In use, the steamed and roasted camellia seeds are transported to the storage tank 7 via the feeding mechanism (not shown in the diagram). A steel hoop and a wrapping bag for packaging the initial camellia cake are placed inside the camellia cake mold 3. Then, the first moving mechanism 2 operates, moving the camellia cake mold 3 containing the steel hoop and wrapping bag towards the guide cylinder 10. Once the camellia cake mold 3 is directly below the guide cylinder 10, the first moving mechanism 2 stops operating. The second moving mechanism 9 then starts operating, moving the guide cylinder 10 downwards along the discharge cylinder 12. During the downward movement of the guide cylinder 10, the sealing component is opened. Next, the conveying mechanism 8 starts, transporting the steamed and roasted camellia seeds from the storage tank 7 along the discharge cylinder 12 and the guide cylinder 10 to the camellia cake mold 3 below, completing the feeding operation. After the material is fed, the second moving mechanism 9 reverses its operation, driving the guide cylinder 10 to move upward, causing the sealing component to close and shut off the discharge channel. At the same time, the first moving mechanism 2 moves in the opposite direction, transporting the oil tea cake mold 3 that has been fed to the lower end of the pressing mechanism 6 on one side. The other empty oil tea cake mold 3 moves to the lower end of the guide cylinder 10 to prepare for feeding, so that the feeding and pressing operations are carried out simultaneously. After the tea seed cake mold 3, which has been filled with material, reaches the lower end of the pressing mechanism 6, the operator first wraps the upper end of the packaging bag over the upper end of the tea seed raw material. Then, the pressing mechanism 6 starts to press the tea seeds inside the tea seed cake mold 3, pressing and packaging the loose tea seeds into the initial tea seed cake. After pressing, the pressing mechanism 6 works in reverse, which will drive the lifting component 13 to move upward together. After the lifting component 13 contacts the transmission component 14, it will also drive the transmission component 14 to move upward. As the transmission component 14 moves upward, after the transmission component 14 contacts the ejection component 15, it pushes the ejection component 15. With the cooperation of the ejection component 15, the initial tea seed cake in the tea seed cake mold 3 is ejected. The operator only needs to directly remove the ejected initial tea seed cake without manually reaching into the mold to take it out, thus avoiding the initial tea seed cake being broken.
[0044] The first moving mechanism 2 includes a moving plate 201, a first motor 202, a first bearing seat 203, a first threaded rod 204, and a moving block 205. The first motor 202 and the first bearing seat 203 are fixedly connected to the upper end of the worktable 1. The first threaded rod 204 is rotatably connected inside the first bearing seat 203. The output end of the first motor 202 is fixedly connected to the first threaded rod 204. The moving block 205 is threadedly connected to the first threaded rod 204. The moving plate 201 is fixedly connected to the upper end of the moving block 205. The upper end of the moving plate 201 is fixed to the camellia cake grinding mold. The movable plate 201 is connected to sliders 5 on both the front and rear sides of its lower end, and the worktable 1 is connected to a first slide rail 4 on its upper end. The first slide rail 4 and sliders 5 are slidably connected. During operation, the first motor 202 starts and drives the first threaded rod 204 to rotate. The rotation of the first threaded rod 204 drives the movable block 205 to move along the direction of the first threaded rod 204 through thread transmission. This, in turn, drives the movable plate 201 to smoothly move the two tea cake molds 3 as a whole with the sliding assistance of sliders 5 and the first slide rail 4, thereby completing the switching of the two tea cake molds 3.
[0045] The second moving mechanism 9 includes a second bearing seat 901, a fourth motor 902, a moving arm 903, a third threaded rod 904, and a second slide rail 905. The fourth motor 902, the second slide rail 905, and the second bearing seat 901 are fixedly connected to the front end of the support frame 11. The third threaded rod 904 is rotatably connected inside the second bearing seat 901. The output end of the fourth motor 902 is fixedly connected to the third threaded rod 904. The moving arm 903 is threadedly connected to the third threaded rod 904. The moving arm 903 is fixedly connected to the guide cylinder 10 and slidably connected to the second slide rail 905. During operation, the fourth motor 902 starts and drives the third threaded rod 904 to rotate. The rotation of the third threaded rod 904 drives the moving arm 903 to move up and down with the sliding assistance of the second slide rail 905 through thread transmission. This, in turn, drives the guide cylinder 10 to move up and down along the discharge cylinder 12, thereby realizing the lifting and lowering control of the guide cylinder 10.
[0046] The sealing assembly includes a sealing seat 16, a sealing ball 17, and a fixing frame 18. The sealing seat 16 is fixedly connected inside the discharge cylinder 12. The fixing frame 18 is fixedly connected inside the guide cylinder 10. The sealing ball 17 is fixedly connected to the upper end of the fixing frame 18. The sealing ball 17 cooperates with the sealing seat 16. When the guide cylinder 10 moves upward, the sealing ball 17 moves upward with it and fits against the sealing seat 16 to seal the discharge cylinder 12. When the guide cylinder 10 moves downward, the sealing ball 17 moves downward with it and disengages from the sealing seat 16, thereby opening the discharge cylinder 12 and completing the on / off control of the discharge channel.
[0047] The material conveying mechanism 8 includes a third motor 801, a rotating shaft 802, and an auger blade 803. The rotating shaft 802 is rotatably connected inside the storage tank 7, and the auger blade 803 is fixedly connected to the rotating shaft 802. The third motor 801 is fixedly connected to the upper end of the storage tank 7, and the output end of the third motor 801 is fixedly connected to the rotating shaft 802. When working, the third motor 801 starts and drives the rotating shaft 802 to rotate, which in turn drives the auger blade 803 to rotate. The rotating auger blade 803 continuously conveys the steamed and roasted camellia seeds in the storage tank 7 downwards, achieving stable material conveying.
[0048] The pressing mechanism 6 includes a support column 601, a second motor 602, a second threaded rod 603, an L-shaped cantilever 604, and a pressure plate 605. The support column 601 is fixedly connected to the upper end of the worktable 1. The second threaded rod 603 is rotatably connected inside the support column 601. The L-shaped cantilever 604 is threaded onto the second threaded rod 603. The L-shaped cantilever 604 is slidably connected to the support column 601. The end of the L-shaped cantilever 604 furthest from the second threaded rod 603 is fixedly connected to the pressure plate 605. A second motor 602 is fixedly connected to the upper end of 601. The output end of the second motor 602 is fixedly connected to the second threaded rod 603. When working, the second motor 602 starts and drives the second threaded rod 603 to rotate. The rotation of the second threaded rod 603 drives the L-shaped cantilever 604 to move up and down along the support column 601 through thread transmission, which in turn drives the pressure plate 605 to complete the up and down movement. During the downward movement of the pressure plate 605, the steamed and roasted camellia seed raw materials in the camellia cake mold 3 are packaged and pressed.
[0049] The lifting assembly 13 includes a movable frame 1301, a screw 1302, a lifting plate 1303, a guide rod 1304, and a handle 1305. The movable frame 1301 is located at the lower end of the worktable 1, with its upper end penetrating the worktable 1 and slidably connected to it. The movable frame 1301 is fixedly connected to the L-shaped cantilever 604. The screw 1302 is threadedly connected to the lower end of the movable frame 1301, and the lifting plate 1303 is rotatably connected to the upper end of the screw 1302. The handle 1305 is fixedly connected to the lower end of the screw 1302. The guide rod 1305 is fixedly connected to the lower end of the lifting plate 1303. 304. The lower end of the guide rod 1304 passes through the movable frame 1301 and is slidably connected to the movable frame 1301. During operation, the handle 1305 is turned to drive the screw 1302 to rotate, which in turn drives the lifting plate 1303 to move up and down under the action of the guide rod 1304. This can change the height of the lifting plate 1303 so that the ejection component 15 can completely eject the initial tea cake from the tea cake mold 3. After the height of the lifting plate 1303 is adjusted, the moving frame 1301 will rise synchronously as the L-shaped cantilever 604 rises, which facilitates the transmission of the rising power to the transmission component 14.
[0050] The transmission assembly 14 includes a U-shaped frame 1401, a spring 1402, and a baffle 1403. The U-shaped frame 1401 is slidably connected inside the worktable 1, with the upper end of the U-shaped frame 1401 passing through the worktable 1. The baffle 1403 is fixedly connected to the upper end of the U-shaped frame 1401. The spring 1402 is fixedly connected to the U-shaped frame 1401, with the upper end of the spring 1402 fixedly connected to the worktable 1. During operation, when the lifting plate 1303 moves upward, the lifting plate 1303 will contact the lower end of the U-shaped frame 1401 and push the U-shaped frame 1401 and the baffle 1403 to move upward, thus completing the power transmission. At the same time, the upward movement of the U-shaped frame 1401 also compresses the spring 1402. When the lifting plate 1303 moves downward, the compressed spring 1402 pulls the U-shaped frame 1401 and the baffle 1403 to reset, waiting for the next operation.
[0051] The ejection assembly 15 includes a lifting rod 1501, a lifting plate 1502, and a mating plate 1503. The lifting rod 1501 is slidably connected inside the moving plate 201. The lifting plate 1502 is fixedly connected to the upper end of the lifting rod 1501. The lifting plate 1502 is slidably connected to the camellia cake mold 3. The mating plate 1503 is fixedly connected to the lower end of the lifting rod 1501. The mating plate 1503 corresponds to the baffle 1403. During operation, as the baffle 1403 moves upward, it contacts the mating plate 1503 and pushes the mating plate 1503 upward. Then, with the cooperation of the lifting rod 1501, it also drives the lifting plate 1502 upward. As the lifting plate 1502 moves upward, the initial camellia cake in the camellia cake mold 3 is ejected upward, which is beneficial for workers to remove the packaged initial camellia cake.
[0052] A method of using a packaging device for camellia oil production, utilizing the aforementioned packaging device for camellia oil production, includes the following steps:
[0053] S1: Pour the steamed and roasted camellia seeds into the storage bucket 7, and place the steel hoop and wrapping bag into the camellia cake mold 3;
[0054] S2: The first moving mechanism 2 drives the camellia cake mold 3 to move, so that one of the camellia cake molds 3 reaches the lower end of the guide cylinder 10;
[0055] S3: After the tea cake mold 3 reaches the lower end of the guide cylinder 10, the second moving mechanism 9 works to drive the guide cylinder 10 to move down and open the sealing component;
[0056] S4: After the sealing component is opened, the feeding mechanism 8 works to transport the steamed and roasted camellia seeds inside the storage tank 7 into the camellia cake mold 3 to achieve the purpose of feeding;
[0057] S5: After the material is loaded into the camellia cake mold 3, the first moving mechanism 2 works in reverse, driving the camellia cake mold 3 to the lower end of the pressing mechanism 6. With the cooperation of the pressing mechanism 6, the raw materials inside the camellia cake mold 3 are pressed and packaged into the initial camellia cake.
[0058] S6: After the initial camellia cake is pressed, the pressing mechanism 6 reverses its operation, so that the pressing plate 605 no longer presses the initial camellia cake, and at the same time, it drives the lifting component 13 to move upward. After the lifting component 13 contacts the transmission component 14, it also drives the transmission component 14 to move upward. As the transmission component 14 moves upward, after the transmission component 14 contacts the ejection component 15, it pushes the ejection component 15 upward. With the cooperation of the ejection component 15, the initial camellia cake in the camellia cake mold 3 is ejected.
[0059] Working principle:
[0060] The steamed and roasted camellia seeds are transported to the storage tank 7 via a feeding mechanism (not shown in the diagram). Steel hoops and wrapping bags for packaging the initial camellia cakes are placed inside the two camellia cake molds 3, respectively. Then, the first moving mechanism 2 is activated, and the first motor 202 drives the first threaded rod 204 to rotate. Through threaded transmission, the moving block 205 and moving plate 201 are moved horizontally, moving one of the camellia cake molds 3 containing the steel hoops and wrapping bags towards the guide cylinder 10. When the camellia cake mold 3 is directly below the guide cylinder 10, the first motor 202 stops working; the second moving mechanism 9 then begins operation. In operation, the fourth motor 902 drives the third threaded rod 904 to rotate, which in turn drives the moving arm 903 to move downward along the second slide rail 905 through the threaded transmission. This in turn drives the guide cylinder 10 to move downward along the discharge cylinder 12. During the downward movement of the guide cylinder 10, the fixed frame 18 and the sealing ball 17 are moved downward, causing the sealing ball 17 to disengage from the sealing seat 16 and the sealing assembly to be opened. Then, the conveying mechanism 8 is started, and the third motor 801 drives the rotating shaft 802 and the auger blade 803 to rotate, conveying the steamed and roasted camellia seeds in the storage tank 7 along the discharge cylinder 12 and the guide cylinder 10 to the camellia cake mold 3 below, completing the feeding operation. After the material is fed, the second moving mechanism 9 reverses its operation, driving the guide cylinder 10 to move upward. The sealing ball 17 moves upward and re-fits with the sealing seat 16, closing the sealing assembly and shutting off the discharge channel. At the same time, the first moving mechanism 2 moves in the opposite direction, transporting the oil tea cake mold 3 that has been fed to the lower end of the pressing mechanism 6 on one side. The other empty oil tea cake mold 3 moves to the lower end of the guide cylinder 10 to prepare for feeding, realizing that the feeding and pressing operations are carried out simultaneously, improving the overall processing efficiency.After the tea seed cake mold 3, having completed its feeding, reaches the lower end of the pressing mechanism 6, the operator first wraps the top of the packaging bag over the top of the tea seed raw material. Then, the pressing mechanism 6 starts, and the second motor 602 drives the second threaded rod 603 to rotate. Through threaded transmission, the L-shaped cantilever 604 moves downward along the support column 601, thereby causing the pressure plate 605 to move downward, pressing the tea seeds inside the tea seed cake mold 3 and packing the loose tea seeds into initial tea seed cakes. After pressing, the pressing mechanism 6 reverses its operation. The second motor 602 drives the second threaded rod 603 to rotate in the opposite direction, causing the L-shaped cantilever 604 and the pressure plate 605 to move upward. During the upward movement of the L-shaped cantilever 604, the moving frame 1301 of the lifting assembly 13 moves upward synchronously. The moving frame 1301 drives... The lifting plate 1303 moves upward and contacts the lower end of the U-shaped frame 1401 of the transmission component 14, pushing the U-shaped frame 1401 and the baffle 1403 upward. At the same time, the spring 1402 is compressed. After the baffle 1403 moves upward, it contacts the mating plate 1503 of the ejection component 15, pushing the mating plate 1503, the lifting rod 1501 and the lifting plate 1502 to move upward as a whole. During the upward movement of the lifting plate 1502, the initial tea cake pressed in the tea cake mold 3 is directly ejected. The operator only needs to directly remove the ejected initial tea cake. When the lifting plate 1303 moves downward with the L-shaped cantilever 604, the compressed spring 1402 will pull the U-shaped frame 1401 and the baffle 1403 to automatically reset, waiting for the next ejection operation.
[0061] Finally, it should be noted that the above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A packaging device for camellia oil production, comprising a workbench (1), characterized in that: The workbench (1) is provided with a first moving mechanism (2) at its upper end. The first moving mechanism (2) is provided with tea cake molds (3) on both sides of its upper end. The tea cake molds (3) are provided with an ejection assembly (15) inside. The ejection assembly (15) is used to eject the initial tea cake in the tea cake mold (3). The workbench (1) is fixedly connected with a support frame (11) at its upper end. The support frame (11) is fixedly connected with a storage tank (7) inside its front end. The storage tank (7) is used to store the steamed and roasted tea seeds. The storage tank (7) is provided with a conveying mechanism (8) inside. The conveying mechanism (8) is used to convey the steamed and roasted tea seeds out. The storage tank (7) is fixedly connected with a discharge cylinder (12) at its lower end. The discharge cylinder (12) is slidably connected with a guide cylinder (10) outside the discharge cylinder (12). The discharge cylinder (12) is equipped with a sealing component inside, which is used to seal the discharge cylinder (12); the support frame (11) is equipped with a second moving mechanism (9) at the front end, which is used to drive the guide cylinder (10) to move up and down; the workbench (1) is equipped with a pressing mechanism (6) at the upper end, and there are two pressing mechanisms (6) located on both sides of the support frame (11). The pressing mechanism (6) is used to press the steamed and fried camellia seeds in the camellia cake mold (3) into an initial camellia cake; the workbench (1) is equipped with a lifting component (13) and a transmission component (14) at the lower end. The lifting component (13) is used to drive the ejection component (15) to eject the initial camellia cake in the camellia cake mold (3) through the transmission component (14).
2. The packaging device for camellia oil production according to claim 1, characterized in that: The first moving mechanism (2) includes a moving plate (201), a first motor (202), a first bearing seat (203), a first threaded rod (204), and a moving block (205). The first motor (202) and the first bearing seat (203) are fixedly connected to the upper end of the worktable (1). The first threaded rod (204) is rotatably connected inside the first bearing seat (203). The output end of the first motor (202) is fixedly connected to the first threaded rod (204). The moving block (205) is threadedly connected to the first threaded rod (204). The moving plate (201) is fixedly connected to the upper end of the moving block (205). The upper end of the moving plate (201) is fixedly connected to the camellia cake mold. The sliders (5) are fixedly connected to the front and rear sides of the lower end of the moving plate (201). The first slide rail (4) is fixedly connected to the upper end of the worktable (1). The first slide rail (4) and the slider (5) are slidably connected.
3. A packaging device for camellia oil production according to claim 1, characterized in that: The second moving mechanism (9) includes a second bearing seat (901), a fourth motor (902), a moving arm (903), a third threaded rod (904), and a second slide rail (905). The fourth motor (902), the second slide rail (905), and the second bearing seat (901) are fixedly connected to the front end of the support frame (11). The third threaded rod (904) is rotatably connected inside the second bearing seat (901). The output end of the fourth motor (902) is fixedly connected to the third threaded rod (904). The moving arm (903) is threadedly connected to the third threaded rod (904). The moving arm (903) is fixedly connected to the guide cylinder (10), and the moving arm (903) is slidably connected to the second slide rail (905).
4. A packaging device for camellia oil production according to claim 1, characterized in that: The sealing assembly includes a sealing seat (16), a sealing ball (17), and a fixing frame (18). The sealing seat (16) is fixedly connected inside the discharge cylinder (12). The fixing frame (18) is fixedly connected inside the guide cylinder (10). The sealing ball (17) is fixedly connected to the upper end of the fixing frame (18). The sealing ball (17) cooperates with the sealing seat (16).
5. A packaging device for camellia oil production according to claim 1, characterized in that: The material conveying mechanism (8) includes a third motor (801), a rotating shaft (802), and an auger blade (803). The rotating shaft (802) is rotatably connected inside the storage tank (7). The auger blade (803) is fixedly connected to the rotating shaft (802). The third motor (801) is fixedly connected to the upper end of the storage tank (7). The output end of the third motor (801) is fixedly connected to the rotating shaft (802).
6. A packaging device for camellia oil production according to claim 2, characterized in that: The pressing mechanism (6) includes a support column (601), a second motor (602), a second threaded rod (603), an L-shaped cantilever (604), and a pressure plate (605). The upper end of the worktable (1) is fixedly connected to the support column (601). The second threaded rod (603) is rotatably connected inside the support column (601). The L-shaped cantilever (604) is threadedly connected to the second threaded rod (603). The L-shaped cantilever (604) is slidably connected to the support column (601). The end of the L-shaped cantilever (604) away from the second threaded rod (603) is fixedly connected to the pressure plate (605). The upper end of the support column (601) is fixedly connected to the second motor (602). The output end of the second motor (602) is fixedly connected to the second threaded rod (603).
7. A packaging device for camellia oil production according to claim 6, characterized in that: The lifting assembly (13) includes a movable frame (1301), a screw (1302), a lifting plate (1303), a guide rod (1304), and a handle (1305). The movable frame (1301) is provided at the lower end of the workbench (1). The upper end of the movable frame (1301) passes through the workbench (1) and is slidably connected to the workbench (1). The movable frame (1301) is fixedly connected to the L-shaped cantilever (604). The screw (1302) is threadedly connected to the lower end of the movable frame (1301). The lifting plate (1303) is rotatably connected to the upper end of the screw (1302). The handle (1305) is fixedly connected to the lower end of the screw (1302). The guide rod (1304) is fixedly connected to the lower end of the lifting plate (1303). The lower end of the guide rod (1304) passes through the movable frame (1301) and is slidably connected to the movable frame (1301).
8. A packaging device for camellia oil production according to claim 7, characterized in that: The transmission assembly (14) includes a U-shaped frame (1401), a spring (1402) and a baffle (1403). The U-shaped frame (1401) is slidably connected inside the workbench (1). The upper end of the U-shaped frame (1401) passes through the workbench (1). The baffle (1403) is fixedly connected to the upper end of the U-shaped frame (1401). The spring (1402) is fixedly connected to the U-shaped frame (1401). The upper end of the spring (1402) is fixedly connected to the workbench (1).
9. A packaging device for camellia oil production according to claim 8, characterized in that: The ejection assembly (15) includes a lifting rod (1501), a lifting plate (1502), and a mating plate (1503). The lifting rod (1501) is slidably connected inside the moving plate (201). The lifting plate (1502) is fixedly connected to the upper end of the lifting rod (1501). The lifting plate (1502) is slidably connected to the tea cake mold (3). The mating plate (1503) is fixedly connected to the lower end of the lifting rod (1501). The mating plate (1503) corresponds to the baffle (1403).
10. A method of using a packaging device for camellia oil production, implemented using the packaging device for camellia oil production as described in any one of claims 1-9, characterized in that, Includes the following steps: S1: Pour the steamed and roasted camellia seeds into the storage bucket (7), and place the steel hoop and wrapping bag into the camellia cake mold (3); S2: The first moving mechanism (2) drives the camellia cake mold (3) to move, so that one of the camellia cake molds (3) reaches the lower end of the guide cylinder (10); S3: After the tea cake mold (3) reaches the lower end of the guide cylinder (10), the second moving mechanism (9) works to drive the guide cylinder (10) to move down and open the sealing assembly; S4: After the sealing component is opened, the feeding mechanism (8) works to transport the steamed and roasted camellia seeds inside the storage bucket (7) to the inside of the camellia cake mold (3) to achieve the purpose of feeding; S5: After the material is loaded into the tea cake mold (3), the first moving mechanism (2) works in reverse, driving the tea cake mold (3) to the lower end of the pressing mechanism (6). With the cooperation of the pressing mechanism (6), the raw materials inside the tea cake mold (3) are pressed and packaged into the initial tea cake. S6: After the initial tea cake is pressed, the pressing mechanism (6) works in reverse, so that the pressing plate (605) no longer presses the initial tea cake, and at the same time drives the lifting component (13) to move up. After the lifting component (13) contacts the transmission component (14), it also drives the transmission component (14) to move up. As the transmission component (14) moves up, after the transmission component (14) contacts the ejection component (15), it pushes the ejection component (15) to the top. With the cooperation of the ejection component (15), the initial tea cake in the tea cake mold (3) is ejected.