Quantitative packaging equipment for tea production

By designing quantitative packaging equipment for tea production, and utilizing the combination of an adjustment port and an electric push rod, the packaging quantity of tea can be flexibly adjusted and blockages can be prevented. This solves the problem that traditional equipment cannot quickly adjust the packaging quantity, and improves production efficiency and equipment applicability.

CN224409709UActive Publication Date: 2026-06-26WUYUAN COUNTY EXCELLENCE BIOLOGICAL FEED CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
WUYUAN COUNTY EXCELLENCE BIOLOGICAL FEED CO LTD
Filing Date
2025-05-14
Publication Date
2026-06-26

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    Figure CN224409709U_ABST
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Abstract

The utility model relates to the technical field of tea production, especially a quantitative packaging equipment for tea production. The utility model provides a quantitative packaging equipment for tea production, which comprises a supporting frame, a placing groove, a hopper, a quantitative groove, a sliding plate, a first electric push rod, a baffle, a controller, a sealing plate, a tension spring, a discharging assembly and a clamping assembly, the supporting frame top is connected with the placing groove, a plurality of hoppers are connected and communicated at the bottom of the placing groove according to a set interval, the hopper bottom is connected and communicated with the quantitative groove, and a plurality of adjusting openings are arranged at the front side of the quantitative groove at equal intervals. By setting adjusting openings with different heights and using the baffle to accurately separate tea leaves according to the required amount of packaged tea leaves, the amount of tea leaves packaged each time can be flexibly adjusted, not only realizing accurate control of the amount of tea leaves packaged, but also increasing the application range of the packaging equipment, so that it can adapt to packaging tasks of different specifications and requirements.
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Description

Technical Field

[0001] This utility model relates to the field of tea production technology, and in particular to a quantitative packaging device for tea production. Background Technology

[0002] In the current tea packaging industry, existing packaging equipment generally suffers from a significant limitation: they struggle to quickly and flexibly adjust the packaging volume of tea. Most traditional tea packaging equipment lacks a flexible and adjustable metering mechanism, resulting in it only being able to provide a fixed packaging capacity, failing to meet the increasingly diverse demands of the market.

[0003] In the traditional approach, to adapt to different packaging needs, companies often have to adopt less efficient methods, such as adding extra components or replacing equipment with different sizes. These methods not only increase production costs but also significantly reduce the flexibility and responsiveness of the production line. Furthermore, the time required for equipment modification or debugging with each adjustment also reduces production efficiency. Utility Model Content

[0004] To overcome the aforementioned shortcomings, the technical problem to be solved is to provide a quantitative packaging device for tea production.

[0005] The technical implementation scheme of this utility model is as follows: A quantitative packaging device for tea production includes a support frame, a placement trough, a funnel, a quantitative trough, a sliding plate, a first electric push rod, a baffle, a controller, a sealing plate, a tension spring, a discharge component, and a positioning component. The top of the support frame is connected to the placement trough, and the bottom of the placement trough is connected and connected to multiple funnels at set intervals. The bottom of each funnel is connected and connected to a quantitative trough. Several adjustment ports are equidistantly opened on the front side of the quantitative trough. A sliding plate is slidably connected vertically on the front side of the quantitative trough and can completely cover all adjustment ports. The left side of the quantitative trough is equidistantly connected to a sealing plate with the same number of adjustment ports. A tension spring is connected between the sealing plate and the quantitative trough. Initially, the sliding plate abuts against the sealing plate. A first electric push rod is installed on the front side of each sliding plate. A baffle penetrating the sliding plate is connected to the telescopic rod of the first electric push rod. The baffle is inserted into the quantitative trough through one of the adjustment ports. A controller is installed on the right side of the front part of the support frame, and the first electric push rod is electrically connected to the controller.

[0006] Furthermore, it is particularly preferred that the discharge assembly includes a second electric push rod, a switch plate, and a moving rod. The lower part of the leftmost metering trough is connected to the second electric push rod, which is electrically connected to the controller. The moving rod is connected to the telescopic rod of the second electric push rod, and the moving rod has switch plates fixed at equal intervals, the same number as the metering troughs. Each switch plate can accurately align with and close the bottom opening of the corresponding metering trough.

[0007] Furthermore, it is particularly preferred that the positioning assembly includes a slide groove, a sleeve, a locking hole, a return spring, and a pin. The right side of the metering groove is connected to a slide groove, and the front side of the slide groove is provided with locking holes at intervals equal to the number of adjustment ports. The upper front side of the sliding plate is connected to a sleeve, and a pin is slidably connected inside the sleeve. The pin can be inserted into the locking hole at the same height, and two return springs are connected between the pin and the inside of the sleeve.

[0008] Furthermore, it is particularly preferred that the device also includes inclined blocks, with multiple inclined blocks being connected at equal intervals within the placement slot.

[0009] Furthermore, it is particularly preferred that the device also includes an observation plate, with a transparent observation plate connected to the center of the front side of the placement slot.

[0010] In addition, it is particularly preferred that the device also includes a third electric push rod and a drain rod. The third electric push rod is installed on the upper left side of the metering tank. The drain rod is connected to the telescopic rod of the third electric push rod. The drain rod penetrates the inside of the funnel. The third electric push rod is electrically connected to the controller.

[0011] The beneficial effects are as follows: 1. By setting adjustment ports of different heights and using baffles to precisely separate the tea leaves according to the required amount of tea to be packaged, the amount of tea leaves packaged each time can be flexibly adjusted. This not only achieves precise control over the amount of tea leaves packaged, but also increases the applicability of the packaging equipment, enabling it to adapt to packaging tasks of different specifications and requirements.

[0012] 2. The device is designed with a dredging rod that works in conjunction with a third electric push rod to automatically agitate the tea leaves in the funnel during the tea feeding process. This effectively avoids channel blockage caused by tea leaf accumulation, ensuring the continuity and stability of production. In addition, operators can easily start or stop the dredging function through the controller, further improving work efficiency. Attached Figure Description

[0013] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0014] Figure 2 This is a three-dimensional structural diagram of the placement groove and inclined block components of this utility model.

[0015] Figure 3 This is a three-dimensional structural diagram of the funnel, chute, and second electric push rod of this utility model.

[0016] Figure 4 This is a three-dimensional structural diagram of the funnel, metering trough, and adjusting port of this utility model.

[0017] Figure 5 This is a three-dimensional structural diagram of the components of this utility model, including the slide groove, sliding plate, and first electric push rod.

[0018] Figure 6 This is a three-dimensional structural diagram of the sleeve, pin, and return spring components of this utility model.

[0019] Figure 7 This is a three-dimensional structural diagram of the third electric push rod and the unblocking rod component of this utility model.

[0020] The markings in the diagram are as follows: 1-Support frame, 2-Placement groove, 21-Inclined block, 22-Observation plate, 3-Function funnel, 31-Quantitative groove, 32-Adjustment port, 4-Slide groove, 41-Sliding plate, 42-First electric push rod, 43-Baffle, 44-Sleeve, 45-Clamping hole, 46-Reset spring, 47-Pin, 5-Second electric push rod, 51-Switch plate, 52-Moving rod, 6-Third electric push rod, 61-Unblocking rod, 7-Controller, 81-Sealing plate, 82-Tension spring. Detailed Implementation

[0021] The technical solution of this utility model will be further described below with reference to the accompanying drawings.

[0022] Example: A quantitative packaging device for tea production, such as... Figures 1-6As shown, the assembly includes a support frame 1, a placement trough 2, inclined blocks 21, an observation plate 22, funnels 3, a metering trough 31, a sliding plate 41, a first electric push rod 42, a baffle 43, a controller 7, a sealing plate 81, a tension spring 82, a discharge assembly, and a positioning assembly. The top of the support frame 1 is connected to the placement trough 2 for storing tea leaves to be packaged. A transparent observation plate 22 is connected to the middle of the front side of the placement trough 2, allowing easy monitoring of the tea leaf storage level and timely replenishment. Multiple funnels 3 are connected and connected at set intervals at the bottom of the placement trough 2. The bottom of each funnel 3 is connected and connected to a metering trough 31, ensuring that the tea leaves falling from the placement trough 2 accurately enter each metering trough 31 for metering. Multiple inclined blocks 21 are equidistantly connected within the placement trough 2 to separate the flow channels from the funnels 3, ensuring smooth flow of the tea leaves during the feeding process. The front side of the metering trough 31 is equidistantly connected... The metering trough 31 is provided with several adjustment ports 32. Each of the front sides of the metering trough 31 is vertically slidably connected to a sliding plate 41, which can completely cover all the adjustment ports 32. The left side of the metering trough 31 is equidistantly connected to a sealing plate 81 with the same number of adjustment ports 32. Each sealing plate 81 and the metering trough 31 is connected to a tension spring 82. Initially, the sliding plate 41 abuts against the sealing plate 81, and the tension spring 82 is in a stretched state. Each of the front sides of the sliding plate 41 is equipped with a first electric push rod 42. Each of the first electric push rod 42 has a baffle 43 that penetrates through the sliding plate 41. The baffle 43 is inserted into the metering trough 31 through one of the adjustment ports 32 to achieve effective separation of tea leaves. The front right side of the support frame 1 is bolted to a controller 7. The first electric push rod 42 is electrically connected to the controller 7. The support frame 1 has a groove located directly below the metering trough 31 to stably place the empty can and facilitate subsequent tea filling operations.

[0023] like Figure 3 As shown, the discharge assembly includes a second electric push rod 5, a switch plate 51, and a moving rod 52. The lower part of the leftmost metering trough 31 is bolted to the second electric push rod 5. The second electric push rod 5 is electrically connected to the controller 7. The moving rod 52 is connected to the telescopic rod of the second electric push rod 5. The same number of switch plates 51 as the metering trough 31 are fixed on the moving rod 52 at equal intervals. Each switch plate 51 can accurately align with and close the bottom opening of the corresponding metering trough 31. By controlling the movement of the second electric push rod 5, the switch plates 51 can be moved synchronously, thereby controlling the timing of tea leaves flowing out of the metering trough 31.

[0024] like Figures 3-6As shown, the locking assembly includes a sliding groove 4, a sleeve 44, locking holes 45, a return spring 46, and a pin 47. The right side of the metering groove 31 is connected to the sliding groove 4. The front side of the sliding groove 4 is provided with locking holes 45 of the same number as the adjustment port 32. The upper front side of the sliding plate 41 is welded with a sleeve 44. The sleeve 44 is slidably connected with a pin 47. The pin 47 can be inserted into the locking holes 45 at the same height to lock the position of the sliding plate 41 and ensure the stability of the tea metering process. Two return springs 46 are connected between the pin 47 and the inside of the sleeve 44.

[0025] like Figure 3 and Figure 7 As shown, it also includes a third electric push rod 6 and a clearing rod 61. The third electric push rod 6 is bolted to the upper left side of the metering trough 31. The clearing rod 61 is connected to the telescopic rod of the third electric push rod 6. The clearing rod 61 penetrates the inside of the funnel 3. The third electric push rod 6 is electrically connected to the controller 7. The controller 7 is operated to start the third electric push rod 6 and control the extension and retraction of its telescopic rod, thereby driving the clearing rod 61 to move up and down. This can stir the tea in the funnel 3 during the tea feeding process, prevent the tea from blocking the feeding channel, and ensure the smooth feeding process. After the clearing operation is completed, the action of the clearing rod 61 can be stopped by turning off the third electric push rod 6.

[0026] When packaging tea in measured quantities, the tea is first added to the placement trough 2. The tea will fall through the funnel 3 into each measuring trough 31. Based on the required amount of tea to be packaged, the controller 7 is operated to activate the first electric push rod 42, causing its extension rod to extend and move the baffle 43 forward, disengaging it from the measuring trough 31, thus filling the measuring trough 31 with tea. The measuring trough 31 has adjustable openings 32 at different heights to accommodate different packaging needs. Next, based on the required amount of tea to be packaged, the height of the sliding plate 41 and the baffle 43 is adjusted. The pin 47 is pulled forward, stretching the return spring 46 and disengaging the pin 47 from the locking hole 45. Then, the sliding plate 41 is pushed downwards, thereby driving the first electric push rod 42 and... The baffle 43 moves downward to a suitable height. During the movement of the baffle 43, when it no longer blocks the corresponding sealing plate 81, the tension spring 82 will cause the sealing plate 81 to move to the right to block the adjustment port 32 at the same height, preventing tea leaves from flowing out through these adjustment ports 32. After the baffle 43 is adjusted to a suitable height, the pin 47 is released, and the return spring 46 rebounds to make the pin 47 re-engage with the locking hole 45, fixing the position of the sliding plate 41. Then, the first electric push rod 42 is controlled to shorten and reset, driving the baffle 43 to move backward and insert into the adjustment port 32, separating the tea leaves in the metering groove 31. At this time, the amount of tea leaves from the baffle 43 down to the bottom of the metering groove 31 is the amount of tea leaves to be packaged.

[0027] Place the can in the groove on the support frame 1 below the metering trough 31. Operate the controller 7 to start the second electric push rod 5, controlling its extension rod to extend and drive the moving rod 52 to move to the right, thereby driving the switch plate 51 to move to the right, opening the bottom opening of the metering trough 31. The tea leaves will then fall into the can to complete the packaging. After the filling is complete, control the extension rod of the second electric push rod 5 to shorten and reset, driving the moving rod 52 and the switch plate 51 to move to the left and reset, closing the bottom opening of the metering trough 31. If further operation is required, the first electric push rod 42 can drive the baffle 43 to move forward, no longer blocking the tea leaves in the metering trough 31, allowing the tea leaves above to fall and fill the metering trough 31. Then reset the baffle 43 again to continue metering and separating the tea leaves, preparing for the next packaging. If it is necessary to adjust the height of the sliding plate 41 and the baffle 43 upwards, the sealing plate 81 blocking the adjustment port 32 must be manually pushed to the left to reset, so that the tension spring 82 returns to the tensioned state, and then the height of the sliding plate 41 and the baffle 43 can be adjusted.

[0028] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model and are not intended to limit the scope of protection of this utility model. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this utility model without departing from the essence and scope of the technical solutions of this utility model.

Claims

1. A quantitative packaging device for tea production, characterized in that: The device includes a support frame (1), a placement trough (2), a funnel (3), a metering trough (31), a sliding plate (41), a first electric push rod (42), a baffle (43), a controller (7), a sealing plate (81), a tension spring (82), a discharge assembly, and a positioning assembly. The top of the support frame (1) is connected to the placement trough (2). The bottom of the placement trough (2) is connected and connected to multiple funnels (3) at set intervals. The bottom of each funnel (3) is connected and connected to a metering trough (31). The front side of each metering trough (31) is provided with several adjustment ports (32) at equal intervals. The front side of each metering trough (31) is vertically slidably connected to a sliding plate (41) that can completely cover all adjustment ports (32). 2) A sealing plate (81) with the same number of adjustment ports (32) is equidistantly connected to the left side of the metering groove (31). A tension spring (82) is connected between the sealing plate (81) and the metering groove (31). Initially, the sliding plate (41) abuts against the sealing plate (81). A first electric push rod (42) is installed on the front side of the sliding plate (41). A baffle (43) that penetrates the sliding plate (41) is connected to the telescopic rod of the first electric push rod (42). The baffle (43) is inserted into the metering groove (31) through one of the adjustment ports (32). A controller (7) is installed on the right side of the front part of the support frame (1). The first electric push rod (42) is electrically connected to the controller (7).

2. The quantitative packaging equipment for tea production as described in claim 1, characterized in that: The discharge assembly includes a second electric push rod (5), a switch plate (51), and a moving rod (52). The second electric push rod (5) is connected to the lower part of the leftmost metering trough (31). The second electric push rod (5) is electrically connected to the controller (7). The moving rod (52) is connected to the telescopic rod of the second electric push rod (5). The moving rod (52) is fixed with the same number of switch plates (51) as the metering trough (31) at equal intervals. Each switch plate (51) can accurately align with and close the bottom opening of the corresponding metering trough (31).

3. The quantitative packaging equipment for tea production as described in claim 2, characterized in that: The positioning assembly includes a slide groove (4), a sleeve (44), a locking hole (45), a return spring (46), and a pin (47). The right side of the metering groove (31) is connected to the slide groove (4). The front side of the slide groove (4) is provided with locking holes (45) of the same number as the adjustment port (32). The upper front side of the sliding plate (41) is connected to the sleeve (44). The sleeve (44) is slidably connected to the pin (47). The pin (47) can be inserted into the locking hole (45) at the same height. Two return springs (46) are connected between the pin (47) and the inside of the sleeve (44).

4. The quantitative packaging equipment for tea production as described in claim 3, characterized in that: It also includes inclined blocks (21), and multiple inclined blocks (21) are connected at equal intervals in the placement slot (2).

5. The quantitative packaging equipment for tea production as described in claim 4, characterized in that: It also includes an observation plate (22), and a transparent observation plate (22) is connected to the middle of the front side of the placement slot (2).

6. The quantitative packaging equipment for tea production as described in claim 5, characterized in that: It also includes a third electric push rod (6) and a dredging rod (61). The third electric push rod (6) is installed on the upper left side of the metering trough (31). The dredging rod (61) is connected to the telescopic rod of the third electric push rod (6). The dredging rod (61) penetrates the inside of the funnel (3). The third electric push rod (6) is electrically connected to the controller (7).