A high efficiency flower roll machine instead of hand shaping
By designing an efficient flower roll machine with cutting, rolling, and shaping mechanisms, the problems of uneven edges and rolling deviation of the dough have been solved, achieving efficient cutting and shaping and improving the forming quality of the flower rolls.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUJIAN HEKOUWEI FOOD IND CO LTD
- Filing Date
- 2025-08-25
- Publication Date
- 2026-07-14
Smart Images

Figure CN224482785U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of food machinery technology, specifically to a high-efficiency flower roll machine that replaces manual shaping. Background Technology
[0002] Steamed buns are a classic and common staple food, available in various flavors such as salt and pepper, sesame paste, and scallion oil. They are nutritious, delicious, and easy to make. With the development of industry, food production now includes large-scale automated or semi-automated production to achieve desired production standards, reduce labor input, and lower costs.
[0003] However, during the production of the dough, if the edges of the dough are uneven or the size of the dough is inconsistent, the dough must be cut before it can be rolled up, which takes a lot of time. At the same time, during the rolling process, a single rolling wheel is often used to roll the dough, which causes the dough to shift during rolling, which is not conducive to subsequent processing. Moreover, after rolling, it is impossible to shape and transport the flower roll, which affects the aesthetics of the flower roll in the later stage. Utility Model Content
[0004] (a) Technical problems to be solved
[0005] To solve the above-mentioned technical problems, this utility model provides a high-efficiency flower roll machine that can replace manual forming.
[0006] (II) Technical Solution
[0007] Based on this, the present invention provides the following technical solution: a high-efficiency flower roll machine that replaces manual forming, including a frame;
[0008] A conveying module is provided at the top of the frame, a cutting mechanism is provided on the left front end of the frame, a winding conveying mechanism is installed in the middle of the frame, the bottom of the cutting mechanism is bolted to the frame, a shaping conveying mechanism is installed at the right end of the frame, and a controller is fixed at the rear end of the shaping conveying mechanism.
[0009] The trimming mechanism includes a protective plate, a crossbar, a support plate, a movable frame, a trimming wheel, a pressure wheel, a support base, a motor, a tapered wheel, and a guide wheel. The bottom of the protective plate is fixed to the frame, the top of the protective plate is bolted to the crossbar, the rear end of the crossbar is fixed to the support plate, the bottom of the support plate is fixed to the frame, the top of the crossbar is movably connected to the movable frame, the middle of the movable frame is movably connected to the trimming wheel, the rear end of the pressure wheel is movably connected to the protective plate, the top of the support base is fixed to the protective plate, the right end of the support base is bolted to the motor, and a guide wheel is provided at the front end of the support base.
[0010] Preferably, a motor is provided at the rear end of the movable frame, and the output end of the motor is connected to the cutting wheel drive.
[0011] Preferably, the conical wheel is arranged at an angle, and the output end of the motor is connected to the conical wheel via a transmission.
[0012] Preferably, the winding and conveying mechanism includes a receiving frame, a movable seat, a locking button, a winding wheel frame, a connecting plate, a first locking button, a movable wheel, a drive structure, a winding wheel, a slide rod, a slide block, a second motor, an auxiliary wheel, a lead screw, and a connecting frame. The bottom of the receiving frame is bolted to the frame. The receiving frame is slidably fitted to the left end of the movable seat. The right end of the movable seat is fixed to the winding wheel frame. The winding wheel frame is slidably fitted to the bottom of the connecting plate. The connecting plate is movably connected to the top of the movable wheel. The winding wheel frame is fixed to the bottom of the drive structure. The front end of the winding wheel is movably connected to the winding wheel frame. The left end of the slide rod is fixed to the winding wheel frame. The left end of the slide block is slidably fitted to the slide rod. The slide block is bolted to the bottom of the second motor. The output end of the second motor is driven by the auxiliary wheel. The left end of the lead screw is movably connected to the receiving frame. The lead screw is threadedly fitted to the bottom of the movable seat. The lead screw is movably connected to the top of the connecting frame. The bottom of the connecting frame is bolted to the frame.
[0013] Preferably, the left end of the movable seat is provided with a sliding groove, and the locking button passes through the sliding groove and engages with the top of the receiving frame via a thread.
[0014] By adopting the above technical solution, the locking button engages with the threaded connection of the receiving frame, and drives the threaded connection at the lower end of the receiving frame to press down the movable seat, thereby limiting the movable seat.
[0015] Preferably, the rear end of the connecting plate is provided with a sliding groove, and the locking button passes through the sliding groove and is threadedly engaged with the winding wheel frame.
[0016] By adopting the above technical solution, the locking button engages with the threaded engagement of the winding wheel frame, and drives the threaded engagement of the winding wheel frame to the lower end, thereby pressing down on the connecting plate and limiting the position of the connecting plate.
[0017] Preferably, the drive structure consists of a drive motor and a pulley set, with the drive motor driving one set of pulleys in the pulley set and the other set of pulleys in the pulley set driving the rear end of the winding wheel.
[0018] By adopting the above technical solution, the driving structure can drive the winding wheel to rotate, thereby enabling the winding wheel to wind up the conveyed dough.
[0019] Preferably, the shaping and conveying mechanism includes a guide seat, a first slider, a pulley, a second slider, a first lead screw, a second locking button, a fixed plate, a third locking button, a guide seat, a movable seat, and a shaping wheel. The left end of the guide seat is fixed to the controller. The first slider and the second slider are arranged opposite each other on both sides of the left end of the guide seat, and both sliders slide in cooperation with the guide seat. The right end of the first lead screw is movably cooperated with the guide seat, and the first lead screw is threadedly cooperated with the middle of the first slider and the second slider respectively. The first lead screw is drivenly connected to the left end of the second locking button. The left end of the first guide seat is fixed to the controller. The first guide seat is fixed to the bottom of the fixed plate. The third locking button passes through the right end of the fixed plate, and the fixed plate is threadedly connected to the right end of the first guide seat. The bottom of the third locking button is movably connected to the movable seat. The movable seat slides along the vertical end of the first guide seat, and the movable seat is movably connected to the right end of the shaping wheel.
[0020] Preferably, both slider one and slider two are provided with pulleys at their bottoms.
[0021] By adopting the above technical solution, pulleys can be used to guide and extrude the shaped and cut parts from left to right.
[0022] Preferably, the guide seat, slider one, pulley, slider two, lead screw one, and locking button two mutually constitute a central shaping structure, and two sets of central shaping structures are provided. The fixed plate, locking button three, guide seat one, moving seat, and shaping wheel mutually constitute a downward shaping structure, and two sets of downward shaping structures are provided. The central shaping structure and the downward shaping structure are horizontally staggered.
[0023] By adopting the above technical solution, the formed flower rolls can be centered and pressed down for shaping and conveying, so that the flower rolls are arranged neatly and facilitate subsequent processing.
[0024] (III) Beneficial Effects
[0025] Compared with the prior art, this utility model provides a high-efficiency flower roll machine that replaces manual forming, and has the following beneficial effects:
[0026] 1. This high-efficiency flower roll machine, which replaces manual forming, is equipped with an edge-cutting mechanism. The motor drives the edge-cutting wheel to rotate and cut the edges of the conveyed dough to prevent the dough from being too wide or having uneven edges, thus facilitating subsequent processing and increasing the efficiency of rolling.
[0027] 2. This high-efficiency flower roll machine, which replaces manual forming, is equipped with a rolling and conveying mechanism. The drive structure drives the rolling wheel to rotate, causing the rolling wheel to roll the side of the dough to the right. At the same time, the motor drives the auxiliary wheel to rotate. The auxiliary wheel can abut against the other side of the dough that is in contact with the rolling wheel. Through the cooperation of the rolling wheel and the auxiliary wheel, the left and right ends of the rolled dough are guided. The rolling wheel rolls the dough, and the auxiliary wheel guides and limits it to prevent the dough from deviating during rolling, thereby increasing the overall efficiency of the rolling process.
[0028] 3. This high-efficiency flower roll machine, which replaces manual shaping, is equipped with a shaping and conveying mechanism. The shaping wheels can perform vertical positioning and shaping of the flower rolls, while the pulleys of slider one and slider two can perform horizontal positioning and shaping of the flower rolls. The height of the shaping wheels and the distance between the two sets of pulleys can be adjusted as needed to make the overall shape of the flower roll more stable and increase the overall aesthetics of the flower roll after shaping. Attached Figure Description
[0029] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0030] Figure 2 This is a three-dimensional structural diagram of the cutting mechanism of this utility model;
[0031] Figure 3 This is a three-dimensional structural diagram of the winding and conveying mechanism of this utility model;
[0032] Figure 4 This is a three-dimensional structural diagram of the shaping and conveying mechanism of this utility model.
[0033] In the diagram: Frame-1, Conveying Module-2, Edge Trimming Mechanism-3, Rolling Conveying Mechanism-4, Cutting Mechanism-5, Controller-6, Shaping Conveying Mechanism-7;
[0034] Protective plate-31, crossbar-32, support plate-33, movable frame-34, cutting wheel-35, pressure roller-36, support base-37, motor-1-38, tapered wheel-39, guide wheel-310;
[0035] 41. Receiving frame, 42. Movable seat, 43. Locking button, 44. Coil roller frame, 45. Connecting plate, 46. Locking button one, 47. Movable wheel, 48. Drive structure, 49. Coil roller, 410. Slide rod, 411. Slide seat, 412. Motor two, 413. Auxiliary wheel, 414. Lead screw, 415. Connecting frame;
[0036] Guide seat-71, slider one-72, pulley-73, slider two-74, lead screw one-75, locking button two-76, fixing plate-77, locking button three-78, guide seat one-79, moving seat-710, shaping wheel-711. Detailed Implementation
[0037] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0038] Please see Figure 1 A high-efficiency flower roll machine that replaces manual forming includes a frame 1; a conveying module 2 is provided on the top of the frame 1, a cutting mechanism 3 is provided on the left side of the front end of the frame 1, a rolling conveying mechanism 4 is installed in the middle of the frame 1, the bottom of the cutting mechanism 5 is bolted to the frame 1, a shaping conveying mechanism 7 is installed on the right end of the frame 1, and a controller 6 is fixed at the rear end of the shaping conveying mechanism 7.
[0039] In some embodiments, the conveyor module 2 is a common conveyor belt module, which is one of the core standardized components widely used in modern automated production lines, logistics sorting systems, packaging machinery and other fields. It is common knowledge in the field and will not be described in detail here. The controller 6 receives information, makes decisions and issues instructions to achieve precise, efficient and automated control of the conveyor module 2, the trimming mechanism 3, the winding conveyor mechanism 4, the cutting mechanism 5 and the shaping conveyor mechanism 7. The cutting mechanism 5 is mainly composed of a cylinder and a cutter. The cylinder drives the cutter to move downward to cut the rolled flower roll conveyed by the conveyor module 2 to form a suitable size. Of course, the cylinder can also be replaced with a hydraulic cylinder or other components that can perform reciprocating telescopic motion, which is not limited here.
[0040] Please see Figure 2 A high-efficiency flower roll machine that replaces manual forming includes a cutting mechanism 3 comprising a protective plate 31, a crossbar 32, a support plate 33, a movable frame 34, a cutting wheel 35, a pressure wheel 36, a support base 37, a motor 38, a conical wheel 39, and a guide wheel 310. The bottom of the protective plate 31 is fixed to the frame 1, the top of the protective plate 31 is bolted to the crossbar 32, the rear end of the crossbar 32 is fixed to the support plate 33, the bottom of the support plate 33 is fixed to the frame 1, the top of the crossbar 32 is movably connected to the movable frame 34, the middle of the movable frame 34 is movably connected to the cutting wheel 35, the rear end of the pressure wheel 36 is movably connected to the protective plate 31, the top of the support base 37 is fixed to the protective plate 31, the right end of the support base 37 is bolted to the motor 38, and a guide wheel 310 is provided at the front end of the support base 37.
[0041] In this application, a motor is provided at the rear end of the movable frame 34, and the output end of the motor is connected to the cutting wheel 35 for transmission. The conical wheel 39 is set at an inclination, and the output end of the motor 38 is connected to the conical wheel 39 for transmission. The protective plate 31 plays a role in protecting the various components inside the cutting mechanism 3.
[0042] Please see Figure 3 A high-efficiency flower roll machine that replaces manual forming includes a coiling and conveying mechanism 4 comprising a receiving frame 41, a movable seat 42, a locking button 43, a coiling wheel frame 44, a connecting plate 45, a first locking button 46, a movable wheel 47, a drive structure 48, a coiling wheel 49, a slide rod 410, a slide block 411, a second motor 412, an auxiliary wheel 413, a lead screw 414, and a connecting frame 415. The bottom of the receiving frame 41 is bolted to the machine frame 1. The receiving frame 41 is slidably engaged with the left end of the movable seat 42. The right end of the movable seat 42 is fixed with the coiling wheel frame 44, which is slidably engaged with the bottom of the connecting plate 45. The connecting plate 45 is connected to the movable wheel 49. The top of 7 is movably connected, the winding wheel frame 44 is fixed to the bottom of the drive structure 48, the front end of the winding wheel 49 is movably connected to the winding wheel frame 44, the left end of the slide rod 410 is fixed to the winding wheel frame 44, the left end of the slide block 411 is slidably engaged with the slide rod 410, the slide block 411 is bolted to the bottom of the motor 2 412, the output end of the motor 2 412 is driven by the auxiliary wheel 413, the left end of the lead screw 414 is movably connected to the receiving frame 41, the lead screw 414 is threadedly engaged with the bottom of the movable seat 42, the lead screw 414 is movably connected to the top of the connecting frame 415, and the bottom of the connecting frame 415 is bolted to the frame 1.
[0043] In this application, a sliding groove is provided at the left end of the movable seat 42, and a locking button 43 passes through the sliding groove and is threadedly engaged with the top of the receiving frame 41. The locking button 43, through its threaded engagement with the receiving frame 41, drives the threaded transmission to the lower end of the receiving frame 41, pressing down on the movable seat 42 and thus limiting its position. A sliding groove is provided at the rear end of the connecting plate 45, and a locking button 46 passes through the sliding groove and is threadedly engaged with the winding wheel frame 44. The locking button 46, through its threaded engagement with the winding wheel frame 44, drives the threaded transmission to the lower end of the winding wheel frame 44. The connecting plate 45 is pressed down to limit its position. The drive structure 48 consists of a drive motor and a pulley set. The drive motor is driven by one set of pulleys in the pulley set, and the other set of pulleys in the pulley set is driven by the rear end of the winding wheel 49. The drive structure 48 can drive the winding wheel 49 to rotate, so that the winding wheel 49 can wind up the conveyed dough. A locking button can be provided at the connection between the slide block 411 and the slide rod 410 to position the slide block 411.
[0044] Please see Figure 4A high-efficiency flower roll machine that replaces manual shaping includes a shaping and conveying mechanism 7 comprising a guide seat 71, a first slider 72, a pulley 73, a second slider 74, a first lead screw 75, a second locking button 76, a fixed plate 77, a third locking button 78, a first guide seat 79, a movable seat 710, and a shaping wheel 711. The left end of the guide seat 71 is fixed to the controller 6. The first slider 72 and the second slider 74 are arranged opposite each other on both sides of the left end of the guide seat 71, and both sliders 72 and 74 slide in engagement with the guide seat 71. The right end of the first lead screw 75 is movably engaged with the guide seat 71, and the first lead screw 75... Rod 1 75 is threadedly engaged with the middle of slider 1 72 and slider 2 74 respectively. Screw 1 75 is drivenly connected to the left end of locking button 2 76. The left end of guide seat 1 79 is fixed to controller 6. Guide seat 1 79 is fixed to the bottom of fixed plate 77. Locking button 3 78 passes through the right end of fixed plate 77, and fixed plate 77 is threadedly connected to the right end of guide seat 1 79. The bottom of locking button 3 78 is movably connected to moving seat 710. Moving seat 710 slides along the vertical end of guide seat 1 79. Moving seat 710 is movably connected to the right end of shaping wheel 711.
[0045] In some embodiments, both slider 1 72 and slider 2 74 are provided with pulleys 73 at their bottoms. The pulleys 73 can guide and compress the shaped and cut coils to the left and right. The guide seat 71, slider 1 72, pulleys 73, slider 2 74, lead screw 1 75, and locking button 2 76 together form a central shaping structure, and there are two sets of central shaping structures. The fixed plate 77, locking button 3 78, guide seat 1 79, moving seat 710, and shaping wheel 711 together form a downward shaping structure, and there are two sets of downward shaping structures. The central shaping structure and the downward shaping structure are horizontally staggered, which can centrally and downwardly shape and transport the shaped coils, so that the coils are neatly arranged and convenient for subsequent processing. The lead screw 1 75 is provided with opposite spiral threads on its left and right sides, which facilitates the movement of slider 1 72 and slider 2 74 to move apart or closer to each other.
[0046] In summary, during use, the rolled-out dough is placed at the left end of the frame 1 and conveyed by the conveyor module 2. The dough then enters the edge-cutting mechanism 3. During output, the motor 38 drives the edge-cutting wheel 35 to rotate, trimming the edges of the conveyed dough to prevent it from being too wide or having uneven edges. Simultaneously, the pressure roller 36 presses down on the dough to prevent it from deviating from its intended path. The process is then described in the attached diagram. Figure 2 As shown, the conical wheel 39 is driven by motor 38 to rotate, so that the excess dough cut off is separated from the original dough and conveyed to the top of the original dough. Then the cut dough can be collected, rolled out again, and guided by guide wheel 310.
[0047] Next, the cut dough enters the rolling conveyor 4. The drive structure 48 drives the rolling wheel 49 to rotate, causing the rolling wheel 49 to roll the side of the dough to the right, as shown in the attached diagram. Figure 3 As shown, the movable wheel 47 serves as an auxiliary guide, while the motor 412 drives the auxiliary wheel 413 to rotate. The auxiliary wheel 413 can abut against the other side of the dough that is in contact with the rolling wheel 49. Through the cooperation of the rolling wheel 49 and the auxiliary wheel 413, the left and right ends of the rolled dough are guided. The rolling wheel 49 rolls the dough, and the auxiliary wheel 413 guides and limits it to prevent the dough from shifting when it is rolled, which facilitates subsequent processing and increases the overall efficiency of the rolling process.
[0048] Furthermore, by rotating the lead screw 414, the lead screw 414 is threaded into the bottom of the coiling wheel frame 44, causing the coiling wheel frame 44 and the movable seat 42 to shift on the receiving frame 41, thereby adjusting the tilt angle of the coiling wheel 49 to accommodate different coiling thicknesses and coiling requirements. At the same time, the slide seat 411 can be slid on the slide rod 410 to adjust the position of the auxiliary wheel 413 on the coiling wheel frame 44. The position of the connecting plate 45 on the coiling wheel frame 44 can also be adjusted by moving and turning the connecting plate 45, thereby changing the guide position of the movable wheel 47 and flexibly adjusting it to meet different coiling requirements.
[0049] After being rolled up, the dough enters the cutting mechanism 5, where the cylinder drives the cutter to cut the dough into uniformly sized flower rolls.
[0050] Finally, the flower rolls are conveyed to the shaping conveyor 7. The shaping wheel 711 can perform vertical positioning and shaping of the flower rolls, and the pulleys 73 of slider one 72 and slider two 74 can perform horizontal positioning and shaping of the flower rolls, making the overall shape of the flower rolls more stable and increasing the overall aesthetics of the flower rolls after forming.
[0051] Furthermore, by rotating the locking button 3 78 clockwise, the locking button 3 78 engages with the guide seat 1 79, causing the moving seat 710 to move towards the lower end of the guide seat 79, thereby adjusting the height of the shaping wheel 711; by rotating the locking button 2 76 clockwise, the locking button 2 76 drives the lead screw 1 75 to rotate, thereby causing the slider 1 72 and slider 2 74 to slide on the guide seat 71 and move towards the center, adjusting the distance between the two sets of pulleys 73, which facilitates the shaping of flower rolls of different shapes and sizes.
[0052] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A high-efficiency flower roll machine that replaces manual shaping, characterized in that: Includes rack (1); The top of the frame (1) is provided with a conveying module (2), the front left side of the frame (1) is provided with a cutting mechanism (3), the middle part of the frame (1) is provided with a winding conveying mechanism (4), the bottom of the cutting mechanism (5) is bolted to the frame (1), the right end of the frame (1) is provided with a shaping conveying mechanism (7), and the rear end of the shaping conveying mechanism (7) is fixed with a controller (6). The trimming mechanism (3) includes a protective plate (31), a crossbar (32), a support plate (33), a movable frame (34), a trimming wheel (35), a pressure wheel (36), a support base (37), a motor (38), a conical wheel (39), and a guide wheel (310). The bottom of the protective plate (31) is fixed to the frame (1), and the top of the protective plate (31) is bolted to the crossbar (32). The crossbar (32) is fixed to the rear end of the support plate (33). The bottom of (33) is fixedly connected to the frame (1), the crossbar (32) is movably connected to the top of the movable frame (34), the movable frame (34) is movably connected to the middle of the cutting wheel (35), the rear end of the pressure roller (36) is movably connected to the protective plate (31), the top of the support base (37) is fixed to the protective plate (31), the support base (37) is bolted to the right end of the motor (38), and the front end of the support base (37) is provided with a guide wheel (310).
2. The high-efficiency flower roll machine that replaces manual forming according to claim 1, characterized in that: The rear end of the movable frame (34) is equipped with a motor, and the output end of the motor is connected to the cutting wheel (35) for transmission.
3. The high-efficiency flower roll machine that replaces manual forming according to claim 1, characterized in that: The conical wheel (39) is inclined, and the output end of the motor (38) is connected to the conical wheel (39) for transmission.
4. The high-efficiency flower roll machine that replaces manual forming according to claim 1, characterized in that: The winding and conveying mechanism (4) includes a receiving frame (41), a movable seat (42), a locking button (43), a winding wheel frame (44), a connecting plate (45), a locking button (46), a movable wheel (47), and a drive structure (48). The components include a winding wheel (49), a slide rod (410), a slide block (411), a second motor (412), an auxiliary wheel (413), a lead screw (414), and a connecting frame (415). The bottom of the receiving frame (41) is bolted to the frame (1). The receiving frame (41) is slidably fitted to the left end of the movable seat (42). The right end of the movable seat (42) is fixed with a winding wheel frame (44). The winding wheel frame (44) is slidably fitted to the bottom of the connecting plate (45). The connecting plate (45) is movably connected to the top of the movable wheel (47). The winding wheel frame (44) is fixed to the bottom of the drive structure (48). The front of the winding wheel (49) is... The left end of the slide rod (410) is movably connected to the winding wheel frame (44), the left end of the slide block (411) is fixed to the winding wheel frame (44), the left end of the slide block (411) is slidably engaged with the slide rod (410), the slide block (411) is bolted to the bottom of the second motor (412), the output end of the second motor (412) is driven by the auxiliary wheel (413), the left end of the lead screw (414) is movably connected to the receiving frame (41), the lead screw (414) is threaded to the bottom of the movable seat (42), the lead screw (414) is movably connected to the top of the connecting frame (415), and the bottom of the connecting frame (415) is bolted to the machine frame (1).
5. The high-efficiency flower roll machine that replaces manual forming according to claim 4, characterized in that: The movable seat (42) has a sliding groove at its left end, and the locking button (43) passes through the sliding groove and is threaded into the top of the support frame (41).
6. The high-efficiency flower roll machine that replaces manual forming according to claim 4, characterized in that: The rear end of the connecting plate (45) is provided with a sliding groove, and the locking button (46) passes through the sliding groove and is threadedly engaged with the winding wheel frame (44).
7. The high-efficiency flower roll machine that replaces manual forming according to claim 4, characterized in that: The drive structure (48) consists of a drive motor and a pulley set. The drive motor is driven by one set of pulleys in the pulley set, and the other set of pulleys in the pulley set is driven by the rear end of the winding wheel (49).
8. The high-efficiency flower roll machine that replaces manual forming according to claim 1, characterized in that: The shaping and conveying mechanism (7) includes a guide seat (71), a slider one (72), a pulley (73), a slider two (74), a lead screw one (75), a locking button two (76), a fixed plate (77), a locking button three (78), a guide seat one (79), a movable seat (710), and a shaping wheel (711). The left end of the guide seat (71) is fixed to the controller (6). Slider one (72) and slider two (74) are arranged opposite each other on the left side of the guide seat (71), and slider one (72) and slider two (74) are slidably engaged with the guide seat (71). The right end of the lead screw one (75) is movably engaged with the guide seat (71), and the lead screw one (75) is respectively The screw rod (75) is connected to the left end of the locking button (76) in a drive-through connection with the middle thread of slider one (72) and slider two (74). The left end of guide seat one (79) is fixed to the controller (6). Guide seat one (79) is fixed to the bottom of the fixed plate (77). Locking button three (78) passes through the right end of the fixed plate (77), and the fixed plate (77) is threaded to the right end of guide seat one (79). The bottom of locking button three (78) is movably connected to the moving seat (710). The moving seat (710) slides along the vertical end of guide seat one (79). The moving seat (710) is movably connected to the right end of the shaping wheel (711).
9. The high-efficiency flower roll machine according to claim 8, which replaces manual forming, is characterized in that: Both slider one (72) and slider two (74) are provided with pulleys (73) at their bottoms.
10. A high-efficiency flower roll machine that replaces manual forming according to claim 8, characterized in that: The guide seat (71), slider one (72), pulley (73), slider two (74), lead screw one (75), and locking button two (76) constitute a central shaping structure, and there are two sets of central shaping structures. The fixed plate (77), locking button three (78), guide seat one (79), moving seat (710), and shaping wheel (711) constitute a downward shaping structure, and there are two sets of downward shaping structures. The central shaping structure and the downward shaping structure are horizontally staggered.