Positionable cutting bionic flower processing device

By designing a biomimetic flower processing device that includes a storage frame, a movable plate, and a motor drive, the automatic feeding and cutting of flower branch raw materials was realized, solving the problems of low efficiency and poor safety in biomimetic flower processing, and improving the safety and efficiency of biomimetic flower processing.

CN224464756UActive Publication Date: 2026-07-07TIANJIN FEIYI XIANGHE IMPORT & EXPORT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN FEIYI XIANGHE IMPORT & EXPORT CO LTD
Filing Date
2025-07-25
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

The process of cutting flower branches in bionic flowers relies on manual operation or simple mechanical devices, resulting in low efficiency and poor safety.

Method used

Design a biomimetic flower processing device, including a storage frame, a fixed plate, a movable plate, a connecting frame, a crankshaft, a first motor, a conveying component, an unloading component, a positioning component, and a cutting component, to realize automatic feeding and cutting of flower branch raw materials, improve efficiency, and avoid safety hazards.

Benefits of technology

The automated flower cutting device places the raw flower branches in a storage frame during the bionic flower processing. The motor drives the rotating shaft to slide the movable plate, which, together with the fixed plate, realizes the step-by-step transmission, positioning and cutting of the flower branches, improving processing efficiency and avoiding safety hazards.

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Abstract

The utility model relates to the field of flower processing technology especially relates to a bionic flower processing device of positioning cutting, including processing platform, storage frame, fixed plate, movable plate, connecting frame, crankshaft and first motor, storage frame fixed mounting is in one side of processing platform, the inside fixed mounting of storage frame has two groups of fixed plate, the inside of storage frame is provided with three groups movable plate, movable plate and storage frame sliding connection, movable plate and fixed plate high level staggered arrangement, the output fixed mounting of first motor has crankshaft, crankshaft and storage frame rotatory connection, the below fixed mounting of movable plate has connecting frame, connecting frame and crankshaft rotatory connection, the utility model discloses through the rotation of first motor drive pivot, and the rotation of pivot can drive three groups movable plate in the inside synchronous up and down reciprocating sliding of storage frame, thereby cooperation fixed plate can gradually to the flower branch raw material of storage is lifted transmission, and each transmission realizes automatic feeding.
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Description

Technical Field

[0001] This utility model relates to the field of flower processing technology, and in particular to a biomimetic flower processing device that can be positioned and cut. Background Technology

[0002] Bionic flowers are artificial flowers made from materials such as cloth, gauze, silk, plastic, and paper twine, using different processes and techniques, based on fresh flowers. They are not limited by time or season, can maintain their beautiful appearance for a long time, and do not need to be frequently replaced due to withering or fading. Moreover, they are more affordable than fresh flowers.

[0003] The processing of bionic flowers requires the cutting of the flower stems. The cutting process relies heavily on manual operation or simple mechanical devices, which is not only inefficient but also has a low safety factor.

[0004] Therefore, since the processing of the aforementioned bionic flowers requires the cutting of the flower branches, and the cutting steps mostly rely on manual operation or simple mechanical devices, which is not only unsafe but also inefficient, a bionic flower processing device with positioning and cutting capability can be designed to automatically feed and cut the bionic flower branch materials, which is more efficient and avoids safety hazards. Utility Model Content

[0005] To overcome the problem that the processing of bionic flowers requires cutting the flower branches, and the cutting steps mostly rely on manual operation or simple mechanical devices, which is not only inefficient but also has a low safety factor.

[0006] The technical solution of this utility model is as follows: a biomimetic flower processing device with positioning and cutting capability, comprising a processing table, a storage frame, a fixed plate, a movable plate, a connecting frame, a crankshaft, a first motor, a conveying component, an unloading component, a positioning component, and a cutting component. The storage frame is fixedly installed on one side of the processing table. Two sets of fixed plates are fixedly installed inside the storage frame. Three sets of movable plates are arranged inside the storage frame. The movable plates are slidably connected to the storage frame. The movable plates and fixed plates are arranged in an alternating pattern. The upper surfaces of the movable plates and fixed plates are all obliquely cut. The bottom surface inside the storage frame is inclined. The first motor is located below the processing table. The output end of the first motor is fixedly installed with a crankshaft. The other end of the crankshaft is rotatably connected to the storage frame. A connecting frame is fixedly installed below the movable plate. The connecting frame is sleeved around the crankshaft and rotatably connected to the crankshaft. The conveying component is located above the processing table and is located on one side of the uppermost set of movable plates. The unloading component is located on one side of the conveying component. The positioning component is located above the unloading component. The cutting component is located between the conveying component and the unloading component.

[0007] Preferably, a storage frame is used to place the raw flower branches that need to be cut. A first motor drives a rotating shaft to rotate. The rotation of the shaft drives three sets of movable plates to slide up and down synchronously inside the storage frame through a connecting frame. This, together with the fixed plate, gradually raises and transports the stored raw flower branches to the conveying component one by one. The conveying component transports the raw materials, and the positioning component positions the transported raw materials. The cutting component cuts the positioned raw materials, and the finished products are unloaded by the unloading component.

[0008] Preferably, the conveying assembly includes a conveyor belt and a second motor. The conveyor belt is fixedly installed above the processing table, and the second motor is located on one side of the conveyor belt. The output end of the second motor is fixedly connected to the input end of the conveyor belt.

[0009] Preferably, the conveying assembly includes a baffle and a guide plate, the guide plate being fixedly installed above the conveyor belt and located on one side of the storage frame, and the baffle being fixedly installed above the conveyor belt.

[0010] Preferably, the unloading assembly includes a mounting bracket and an unloading ramp. The mounting bracket is fixedly installed above the processing table, and two sets of mounting brackets are provided. The unloading ramp is fixedly installed between the two sets of mounting brackets.

[0011] Preferably, the positioning assembly includes a mounting shaft and an anti-deviation roller. Multiple sets of mounting shafts are provided, with some mounting shafts fixedly installed above the conveyor belt and others fixedly installed above the mounting bracket. The anti-deviation roller is sleeved around the mounting shaft, and the mounting shaft and the anti-deviation roller are rotatably connected.

[0012] Preferably, the positioning assembly includes an internally threaded mounting plate, a threaded rod, and a positioning plate. The internally threaded mounting plate is fixedly mounted on one side of the mounting bracket, the threaded rod passes through the internally threaded mounting plate, and the threaded rod is threadedly connected to the internally threaded mounting plate. One end of the threaded rod is fixedly mounted with a positioning plate.

[0013] Preferably, the cutting assembly includes a gantry frame, a punching device, and a support platform. The gantry frame is fixedly installed above the processing table, the punching device is fixedly installed below the gantry frame, and the support platform is fixedly installed above the processing table, with the support platform and the punching device corresponding to each other.

[0014] The beneficial effects of this utility model are:

[0015] 1. The first motor drives the rotating shaft to rotate. The rotating shaft, through the connecting frame, can drive three sets of movable plates to slide up and down synchronously inside the storage frame. When the movable plate descends, it is level with the set of fixed plates below. The raw materials on the fixed plates roll onto the upper part of the movable plate. As the movable plate rises, when the movable plate is level with the set of movable plates above, the flower branches roll to the next set of movable plates, waiting for the set of movable plates above to descend, until they are pushed onto the conveyor belt. This allows a large number of flower branch raw materials to be transferred one by one to the conveying component, realizing automatic feeding, effectively improving processing efficiency, and avoiding safety hazards.

[0016] 2. The positioning plate can be used to position one end of the raw material being transported. The position of the positioning plate can be adjusted by rotating the threaded rod, thus adapting to the cutting of finished flower branches of different lengths. Attached Figure Description

[0017] Figure 1 The diagram shown is a first three-dimensional structural schematic of the biomimetic flower processing device with positioning and cutting capability according to this utility model.

[0018] Figure 2 The diagram shown is a three-dimensional structural diagram of the internal structure of the storage frame of the biomimetic flower processing device with positioning and cutting capability of this utility model.

[0019] Figure 3 The diagram shown is a second three-dimensional structural schematic of the biomimetic flower processing device with positioning and cutting capability according to this utility model.

[0020] Figure 4 The diagram shown is a three-dimensional cross-sectional view of the biomimetic flower processing device with positioning and cutting capability according to this utility model.

[0021] Explanation of reference numerals in the attached drawings: 1. Processing table; 201. Storage frame; 202. Fixed plate; 203. Movable plate; 204. Connecting frame; 205. Crankshaft; 206. First motor; 301. Conveyor belt; 302. Second motor; 303. Baffle; 304. Guide plate; 401. Mounting bracket; 402. Unloading slope; 501. Mounting shaft; 502. Anti-deviation roller; 503. Internal thread mounting plate; 504. Threaded rod; 505. Positioning plate; 601. Gantry frame; 602. Punching equipment; 603. Support platform. Detailed Implementation

[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0023] Please see Figures 1-4This utility model provides an embodiment: a biomimetic flower processing device with positioning and cutting capability, comprising a processing table 1, a storage frame 201, a fixed plate 202, a movable plate 203, a connecting frame 204, a crankshaft 205, a first motor 206, a conveying assembly, an unloading assembly, a positioning assembly, and a cutting assembly. The storage frame 201 is fixedly installed on one side of the processing table 1. Two sets of fixed plates 202 are fixedly installed inside the storage frame 201. Three sets of movable plates 203 are arranged inside the storage frame 201, and the movable plates 203 are slidably connected to the storage frame 201. The movable plates 203 and the fixed plates 202 are arranged in an alternating pattern, and the upper surfaces of the movable plates 203 and the fixed plates 202 are all beveled. The bottom surface inside the storage frame 201 is inclined. The first motor 206 is located below the processing table 1. The output end of the first motor 206 is fixedly installed with a crankshaft 205, and the other end of the crankshaft 205 is rotatably connected to the storage frame 201. The connecting frame 204 is fixedly installed below the movable plate 203. A connecting frame 204 is sleeved around the crankshaft 205 and rotatably connected to the crankshaft 205. A conveying component is set above the processing table 1 and is located on one side of the uppermost set of movable plates 203. An unloading component is set on one side of the conveying component, a positioning component is set above the unloading component, and a cutting component is set between the conveying component and the unloading component. A storage frame 201 is set to place the flower branch raw materials that need to be cut. A first motor 206 drives the rotating shaft to rotate. The rotation of the rotating shaft can drive the three sets of movable plates 203 to slide up and down synchronously inside the storage frame 201 through the connecting frame 204. This, together with the fixed plate 202, can gradually lift and transport the stored flower branch raw materials one by one to the conveying component. The conveying component transports the raw materials, and the positioning component positions the transported raw materials. The cutting component cuts the positioned raw materials. The finished products after cutting are unloaded by the unloading component.

[0024] Please see Figures 1-2 In this embodiment, the conveying assembly includes a conveyor belt 301 and a second motor 302. The conveyor belt 301 is fixedly installed above the processing table 1, and the second motor 302 is located on one side of the conveyor belt 301. The output end of the second motor 302 is fixedly connected to the input end of the conveyor belt 301. By setting the second motor 302, the conveyor belt 301 can be driven to run, thereby conveying raw materials. The conveying assembly includes a baffle 303 and a guide plate 304. The guide plate 304 is fixedly installed above the conveyor belt 301 and is located on one side of the storage frame 201. The baffle 303 is fixedly installed above the conveyor belt 301. By setting the guide plate 304, the raw materials conveyed by the movable plate 203 can be guided into the conveyor belt 301. By setting the baffle 303, the raw materials entering the conveyor belt 301 are blocked to prevent them from rolling off the conveyor belt 301.

[0025] Please see Figures 3-4 In this embodiment, the unloading assembly includes a mounting bracket 401 and an unloading ramp 402. The mounting bracket 401 is fixedly installed above the processing table 1, and two sets of mounting brackets 401 are provided. The unloading ramp 402 is fixedly installed between the two sets of mounting brackets 401. The unloading ramp 402 and part of the positioning assembly are installed by setting the mounting brackets 401. The unloading ramp 402 can unload the cut finished product. The positioning assembly includes a mounting shaft 501 and an anti-deviation roller 502. Multiple sets of mounting shafts 501 are provided. Part of the mounting shaft 501 is fixedly installed above the conveyor belt 301, and another part of the mounting shaft 501 is fixedly installed above the mounting bracket 401. The anti-deviation roller 502 is sleeved around the mounting shaft 501, and the mounting shaft 501 and the anti-deviation roller 502 are rotatably connected. The anti-deviation roller 502 is installed by setting the mounting shaft 501, and the anti-deviation roller 502 can limit the two sides of the raw material to prevent the raw material from shifting during the cutting process. The positioning component includes an internal thread mounting plate 503, a threaded rod 504, and a positioning... Plate 505 and threaded mounting plate 503 are fixedly installed on one side of mounting bracket 401. Threaded rod 504 passes through threaded mounting plate 503 and is threadedly connected to threaded mounting plate 503. Positioning plate 505 is fixedly installed at one end of threaded rod 504. The threaded rod 504 is installed by setting threaded mounting plate 503, and the positioning plate 505 can position one end of the conveyed raw material. The position of positioning plate 505 can be adjusted by rotating threaded rod 504, thereby adapting to... The cutting assembly is designed for cutting finished flower branches of different lengths. It includes a gantry frame 601, a punching device 602, and a support platform 603. The gantry frame 601 is fixedly installed above the processing table 1, the punching device 602 is fixedly installed below the gantry frame 601, and the support platform 603 is fixedly installed above the processing table 1. The support platform 603 corresponds to the punching device 602. The punching device 602 is installed using the gantry frame 601, and the punching device 602, in conjunction with the support platform 603, can cut the raw materials.

[0026] When working, the longer flower branches are stored in the storage frame 201. The staff needs to arrange the flower branches placed in the storage frame 201 to make them parallel to the movable plate 203.

[0027] The first motor 206 drives the rotating shaft to rotate. The rotation of the rotating shaft can drive three sets of movable plates 203 to slide up and down synchronously inside the storage frame 201 through the connecting frame 204. When the movable plate 203 descends, it is level with the set of fixed plates 202 below. The raw materials on the fixed plate 202 roll above the movable plate 203. As the movable plate 203 rises, when the movable plate 203 is level with the set of movable plates 203 above, the flower branches roll to the next set of movable plates 203, waiting for the set of movable plates above to descend, until they are pushed onto the conveyor belt 301. This allows a large number of flower branch raw materials to be transported one by one, which is convenient for positioning and cutting.

[0028] The guide plate 304 guides the raw materials conveyed by the movable plate 203 into the conveyor belt 301, and the baffle 303 blocks the raw materials entering the conveyor belt 301 to prevent them from rolling off the conveyor belt 301.

[0029] The raw material of the flower branch is transported by the drive conveyor belt 301 until one end of the flower branch contacts the positioning plate 505. The punching equipment 602 can be used in conjunction with the support table 603 to cut the raw material. The cut finished flower branch is output along the unloading slope 402. The above steps are repeated to transport and cut the raw material.

[0030] The anti-deviation roller 502 can limit the two sides of the raw material to prevent it from shifting during the cutting process. The position of the positioning plate 505 can be adjusted by rotating the threaded rod 504, so as to adapt to the cutting of flower branches of different lengths.

[0031] Through the above steps, the first motor 206 drives the rotating shaft to rotate. The rotation of the rotating shaft, through the connecting frame 204, can drive the three sets of movable plates 203 to slide synchronously up and down inside the storage frame 201. In conjunction with the fixed plate 202, the stored flower branch raw materials can be gradually lifted and transported one by one to achieve automatic feeding, effectively improving processing efficiency and avoiding safety hazards. This solves the problem that in the process of processing bionic flowers, the flower branches need to be cut. The cutting steps mostly rely on manual operation or simple mechanical devices, which is not only inefficient but also has a low safety factor.

[0032] The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.

Claims

1. A biomimetic flower processing device with positioning and cutting capability, comprising a processing table (1), characterized in that: It also includes a storage frame (201), a fixed plate (202), a movable plate (203), a connecting frame (204), a crankshaft (205), a first motor (206), a conveying assembly, an unloading assembly, a positioning assembly, and a cutting assembly. The storage frame (201) is fixedly installed on one side of the processing table (1). Two sets of fixed plates (202) are fixedly installed inside the storage frame (201). Three sets of movable plates (203) are provided inside the storage frame (201). The movable plates (203) are slidably connected to the storage frame (201). The movable plates (203) and the fixed plates (202) are arranged in an alternating pattern. The upper surfaces of the movable plates (203) and the fixed plates (202) are all beveled. Inside the storage frame (201) The bottom surface of the part is inclined. The first motor (206) is located below the processing table (1). The output end of the first motor (206) is fixedly installed with a crankshaft (205). The other end of the crankshaft (205) is rotatably connected to the storage frame (201). A connecting frame (204) is fixedly installed below the movable plate (203). The connecting frame (204) is sleeved on the outer periphery of the crankshaft (205). The connecting frame (204) is rotatably connected to the crankshaft (205). The conveying component is located above the processing table (1). The conveying component is located on one side of the uppermost movable plate (203). The unloading component is located on one side of the conveying component. The positioning component is located above the unloading component. The cutting component is located between the conveying component and the unloading component.

2. The biomimetic flower processing device with positioning and cutting capability according to claim 1, characterized in that: The conveying assembly includes a conveyor belt (301) and a second motor (302). The conveyor belt (301) is fixedly installed above the processing table (1), and the second motor (302) is located on one side of the conveyor belt (301). The output end of the second motor (302) is fixedly connected to the input end of the conveyor belt (301).

3. The biomimetic flower processing device with positioning and cutting capability according to claim 2, characterized in that: The conveying assembly includes a baffle (303) and a guide plate (304). The guide plate (304) is fixedly installed above the conveyor belt (301) and is located on one side of the storage frame (201). The baffle (303) is fixedly installed above the conveyor belt (301).

4. The biomimetic flower processing device with positioning and cutting capability according to claim 1, characterized in that: The unloading assembly includes a mounting bracket (401) and an unloading ramp (402). The mounting bracket (401) is fixedly installed above the processing table (1). There are two sets of mounting brackets (401), and the unloading ramp (402) is fixedly installed between the two sets of mounting brackets (401).

5. The biomimetic flower processing device with positioning and cutting capability according to claim 4, characterized in that: The positioning assembly includes a mounting shaft (501) and an anti-deviation roller (502). Multiple sets of mounting shafts (501) are provided. Some mounting shafts (501) are fixedly installed above the conveyor belt (301), and other mounting shafts (501) are fixedly installed above the mounting bracket (401). The anti-deviation roller (502) is sleeved around the mounting shaft (501), and the mounting shaft (501) and the anti-deviation roller (502) are rotatably connected.

6. The biomimetic flower processing device with positioning and cutting capability according to claim 4, characterized in that: The positioning assembly includes an internally threaded mounting plate (503), a threaded rod (504), and a positioning plate (505). The internally threaded mounting plate (503) is fixedly mounted on one side of the mounting bracket (401). The threaded rod (504) passes through the internally threaded mounting plate (503) and is threadedly connected to the internally threaded mounting plate (503). The positioning plate (505) is fixedly mounted on one end of the threaded rod (504).

7. The biomimetic flower processing device with positioning and cutting capability according to claim 1, characterized in that: The cutting assembly includes a gantry (601), a punching device (602), and a support platform (603). The gantry (601) is fixedly installed above the processing table (1), the punching device (602) is fixedly installed below the gantry (601), and the support platform (603) is fixedly installed above the processing table (1). The support platform (603) and the punching device (602) correspond to each other.