A push-back type cutting device for an ai-ember

Abstract

This utility model belongs to the technical field of moxa product processing equipment, and proposes a moxa stick back-pushing cutting device. It includes a frame, on which a feeding device, a stick-jointing device, a stick-pushing device, a stick-pressing device, a cutting device, and a back-pushing device are sequentially arranged. In summary, this utility model can achieve the leveling of both ends of the moxa stick and the cutting of the moxa stick without manual intervention by pushing the moxa stick back, thus improving production efficiency and reducing production costs by simplifying the device structure.

Description

Technical Field

[0001] This utility model belongs to the technical field of moxa product processing equipment, and specifically relates to a moxa stick push-back cutting device. Background Technology

[0002] Currently, moxa sticks need to be cut into moxa cones of a certain length according to customer requirements. When cutting moxa sticks, both ends of the moxa stick need to be slightly trimmed flat, and then the trimmed moxa stick is cut into several moxa cones. The moxa stick cutting machines currently used all have the moxa stick moving forward. When trimming the moxa stick, it is necessary to manually reload the moxa stick in the opposite direction or to use two sets of cutting devices to trim both ends of the moxa stick, which is time-consuming, labor-intensive, and increases equipment costs. Therefore, it is necessary to develop a new moxa stick back-pushing cutting device. Summary of the Invention

[0003] To address the aforementioned problems, this utility model proposes a moxa stick back-pushing cutting device. The purpose is to achieve the flattening and cutting of both ends of the moxa stick by pushing it back without manual intervention, which greatly improves production efficiency and reduces production costs.

[0004] To achieve its purpose, the technical solution adopted by this utility model is to design a moxa stick back-pushing cutting device, characterized by: a frame, on which a feeding device, a stick-jointing device, a stick-pushing device, a stick-pressing device, a cutting device, and a back-pushing device are sequentially arranged; the stick-jointing device is located below the feeding device, and includes a receiving tray and a sliding table module one, with the receiving tray being drivenly connected to the sliding table module one; the stick-pushing device includes a sliding table module two, a front pushing plate, and a pushing channel, with the front end of the pushing channel connected to the receiving tray, and the front pushing plate being drivenly connected to the sliding table module two and straddling the pushing channel; the stick-pressing device is located below the feeding device. The cutting device is located on one side of the pushing channel, below the pressing device, and has a cutting groove on the pushing channel. The cutting device includes a cutting motor, a circular cutter, and a slide module three. The cutting motor is connected to the circular cutter in a driving connection. The return pushing device is located on the opposite side of the pushing device, behind the cutting device. The return pushing device includes a slide module four and a rear pushing plate. The rear pushing plate is connected to the slide module four in a driving connection. A material drop gap is reserved between the rear pushing plate and the end of the pushing channel.

[0005] Furthermore, the feeding device includes a base plate, a baffle, and a feeding cylinder. The base plate is inclined, the baffle presses against the surface of the base plate, and the feeding cylinder is driven by the baffle. The pressing device includes a pressing plate and a pressing cylinder, and the pressing cylinder is driven by the pressing plate. The sliding table module three drives the cutting motor and the circular cutter to reciprocate in a straight line, and the circular cutter moves along the cutting groove. The sliding table module two is set on the side of the pushing channel, and the lower end of the front pushing plate extends into the pushing channel and is adapted to the pushing channel.

[0006] Furthermore, it also includes an air compressor, and the feeding cylinder and the pressing cylinder are both driven by the air compressor; it also includes a controller, and the air compressor, slide modules one, two, three, and four, and the cutting motor are all controlled by the controller.

[0007] Furthermore, a receiving frame is provided below the material drop gap.

[0008] In use, under the control of the controller's preset program, the feeding cylinder drives the baffle to open, and the moxa stick falls into the receiving tray. During the falling process, the receiving tray moves under the drive of the first slide module, so that the moxa sticks evenly fill the feeding tray. After the feeding tray is full, it moves to connect and align with the front end of the pushing channel. The second slide module drives the front pushing plate to push all the moxa sticks into the pushing channel at the same time. The front pushing plate continues to push the moxa sticks under the pressing device. The pressing cylinder drives the pressing plate to press down, pressing and flattening the moxa sticks. The cutting device is started. The third slide module drives the annular cutter to move forward and trim the front end of the moxa stick. After trimming, the annular cutter and pressing plate reset. The front pushing plate pushes the moxa stick forward a distance. The pressing plate and annular cutter move again to complete one cutting action. This process is repeated. After the moxa stick is cut to a certain length, the front pusher plate pushes the remaining moxa stick to the side of the return pusher device in one go. At the same time, the front end of the previously cut moxa stick and the moxa column are pushed into the material drop gap and fall down. At this time, the front pusher plate resets, the slide module drives the rear pusher plate to move, and the rear pusher plate pushes the moxa stick back to the bottom of the pressing device. The pressing cylinder drives the pressing plate to press down, pressing and flattening the remaining moxa stick. The cutting device is started, the slide module drives the annular cutter to move forward, and trims the rear end of the moxa stick. After trimming, the annular cutter and the pressing plate reset, and the rear pusher plate pushes the moxa stick back a certain distance. The pressing plate and the annular cutter move again to complete one column cutting action. This process is repeated until the moxa stick is cut into a column. The rear end of the moxa column and the moxa column cut in the return push process are pushed into the material drop gap by the next moxa stick fed in.

[0009] In summary, this invention enables the trimming of both ends of the moxa stick and the cutting of the moxa stick without manual intervention by pushing the moxa stick back. This improves production efficiency and reduces production costs by simplifying the device structure. Attached Figure Description

[0010] Figure 1 This is a schematic diagram of the overall structure of the present invention. Figure 1 ;

[0011] Figure 2 This is a schematic diagram of the overall structure of the present invention. Figure 2 . Detailed Implementation

[0012] The structure and advantages of this utility model will be further described below with reference to the accompanying drawings and embodiments.

[0013] Example 1, see Figure 1 , 2 A moxa stick back-pushing cutting device includes a frame 1, on which a feeding device 2, a stick-jointing device 3, a stick-pushing device 4, a stick-pressing device 5, a cutting device 6, and a back-pushing device 7 are sequentially arranged. The stick-jointing device 3 is located below the feeding device 2 and includes a receiving tray 3.1 and a sliding table module 3.2. The receiving tray 3.1 is convexly connected to the sliding table module 3.2. The stick-pushing device 4 includes a sliding table module 4.1, a front pushing plate 4.2, and a pushing channel 4.3. The front end of the pushing channel 4.3 is connected to the receiving tray 3.1, and the front pushing plate 4.2 is convexly connected to the sliding table module 4.1 and spans across the pushing channel 4.3. The pressing device... 5 is located on the rear side of the pusher device 4; the cutting device 6 is located on one side of the pusher channel 4.3, below the pusher device 5, and has a knife groove 4.4 on the pusher channel 4.3. The cutting device 6 includes a cutting motor 6.1, a circular cutter 6.2, and a slide module 6.3, with the cutting motor 6.1 and the circular cutter 6.2 being drivenly connected; the return pusher 7 is located on the opposite side of the pusher device 4, behind the cutting device 6, and includes a slide module 7.1 and a rear pusher plate 7.2, with the rear pusher plate 7.2 being drivenly connected to the slide module 7.2. A material drop gap 8 is reserved between the rear pusher plate 7.2 and the end of the pusher channel 4.3.

[0014] Example 2, see Figure 1 , 2 Based on Embodiment 1, the feeding device 2 includes a base plate 2.1, a baffle 2.2, and a feeding cylinder 2.3. The base plate 2.1 is inclined, the baffle 2.2 presses against the surface of the base plate 2.1, and the feeding cylinder 2.3 is drivenly connected to the baffle 2.2. The pressing device 5 includes a pressing plate 5.1 and a pressing cylinder 5.2, which is drivenly connected to the pressing plate 5.1. The sliding table module 3 6.3 drives the cutting motor 6.1 and the circular cutter 6.2 to reciprocate in a straight line, and the circular cutter 6.2 moves along the cutter groove 4.4. The sliding table module 2 4.1 is located on the side of the pushing channel 4.3, and the lower end of the front pushing plate 4.2 extends into the pushing channel 4.3 and is adapted to the pushing channel 4.3.

[0015] Example 3, see Figure 1 , 2 Based on Embodiment 2, it also includes an air compressor, and the feeding cylinder 2.3 and the pressing cylinder 5.2 are both driven by the air compressor; it also includes a controller, and the air compressor, the slide modules 1, 2, 3, and 4 3.2, 4.1, 6.3, and 7.1, and the cutting motor 6.1 are all controlled by the controller.

[0016] Example 4, see Figure 1 , 2 Based on Embodiment 2, a receiving frame is provided below the material drop gap 8.

[0017] The method of using this device is as follows: Under the control of the controller's preset program, the feeding cylinder 2.3 drives the baffle 2.2 to open, and the moxa sticks 9 fall into the receiving tray 3.1. During the falling process of the moxa sticks 9, the receiving tray 3.1 moves under the drive of the sliding module 1 3.2, so that the moxa sticks 9 are evenly filled into the feeding tray 3.1. After the feeding tray 3.1 is full, it moves to connect and align with the front end of the pushing channel 4.3. The sliding module 2 4.1 drives the front pushing plate 4.2 to push all the moxa sticks 9 into the pushing channel simultaneously. Channel 4.3, the front pusher plate 4.2 continues to push the moxa stick 9 below the pressing device 5. The pressing cylinder 5.2 drives the pressing plate 5.1 to press down, pressing and flattening the moxa stick. The cutting device 6 is started, and the sliding module 3 6.3 drives the annular cutter 6.2 forward to flatten the front end of the moxa stick 9. After flattening, the annular cutter 6.2 and the pressing plate 5.1 reset. The front pusher plate 4.2 pushes the moxa stick 9 forward a further distance. The pressing plate 5.1 and the annular cutter 6.2 operate again to complete one cutting cycle. This process repeats itself. When the moxa stick 9 is cut to a certain length, preferably more than halfway, the front pusher plate 4.2 pushes the remaining moxa stick 9 to the side of the return pusher device 7. At the same time, the previously cut-off moxa stick tip and moxa column are pushed into the material drop gap 8 and fall down. At this point, the front pusher plate 4.2 resets, and the slide module 4 7.1 drives the rear pusher plate 7.2 to move. The rear pusher plate 7.2 pushes the moxa stick 9 back to below the pressing device 5. The pressing cylinder 5.2 drives the pressing plate 5.1 to press down, pressing and flattening the remaining moxa stick. 9. Start the cutting device 6. The slide module 3 6.3 drives the ring cutter 6.2 forward to flatten the rear end of the moxa stick 9. After flattening, the ring cutter 6.2 and the pressure plate 5.1 are reset. The pusher plate 7.2 pushes the moxa stick 9 back a distance. The pressure plate 5.1 and the ring cutter 6.2 move again to complete one cutting action. Repeat this process to cut the moxa stick 9 into a column. The rear end of the moxa column cut off in the back push process and the moxa column are pushed into the material drop gap 8 by the next moxa stick 9 to fall.

[0018] Although the present invention has been described in detail above, it is not limited to the specific embodiments described above. The specific embodiments described above are merely illustrative and not restrictive. Those skilled in the art can make many modifications under the guidance of the present invention and without departing from its spirit, and all such modifications are within the protection scope of the present invention.

Claims

1. A moxa stick push-back type cutting device, characterized in that: The device includes a frame, on which are sequentially arranged a feeding device, a strip receiving device, a strip pushing device, a strip pressing device, a cutting device, and a return pushing device. The strip receiving device is located below the feeding device and includes a receiving tray and a first slide module, with the receiving tray being drivenly connected to the first slide module. The strip pushing device includes a second slide module, a front pushing plate, and a pushing channel. The front end of the pushing channel is connected to the receiving tray, and the front pushing plate is drivenly connected to the second slide module and spans across the pushing channel. The strip pressing device is located below the feeding device. The cutting device is located on one side of the pushing channel, below the pressing device, and has a cutting groove on the pushing channel. The cutting device includes a cutting motor, a circular cutter, and a slide module three. The cutting motor is connected to the circular cutter in a driving connection. The return pushing device is located on the opposite side of the pushing device, behind the cutting device. The return pushing device includes a slide module four and a rear pushing plate. The rear pushing plate is connected to the slide module four in a driving connection. A material drop gap is reserved between the rear pushing plate and the end of the pushing channel.

2. The moxa stick push-back cutting device as described in claim 1, characterized in that: The feeding device includes a base plate, a baffle, and a feeding cylinder. The base plate is inclined, the baffle presses against the surface of the base plate, and the feeding cylinder is driven by the baffle. The pressing device includes a pressing plate and a pressing cylinder, and the pressing cylinder is driven by the pressing plate. The sliding table module three drives the cutting motor and the circular cutter to reciprocate in a straight line, and the circular cutter moves along the cutting groove. The sliding table module two is set on the side of the pushing channel, and the lower end of the front pushing plate extends into the pushing channel and is adapted to the pushing channel.

3. The moxa stick push-back cutting device as described in claim 2, characterized in that: It also includes an air compressor, and the feeding cylinder and the pressing cylinder are both driven by the air compressor; it also includes a controller, and the air compressor, slide modules one, two, three, and four, and the cutting motor are all controlled by the controller.

4. The moxa stick push-back cutting device as described in claim 2, characterized in that: A receiving frame is provided below the material drop gap.

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