Multifunctional material preparation device

By using the platform components of the multi-functional material preparation device to automatically descend and recycle components, the problems of insufficient efficiency and ergonomics in the existing unpacking operation mode are solved, realizing continuous operation of unpacking and cardboard recycling, and improving overall operation efficiency and ease of operation.

CN224491795UActive Publication Date: 2026-07-14GREE ELECTRIC APPLIANCES WUHAN

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GREE ELECTRIC APPLIANCES WUHAN
Filing Date
2025-07-23
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

The existing unpacking operation mode has fundamental shortcomings in terms of operational efficiency, ergonomics, and process continuity. In particular, the forced separation of material unpacking and cardboard recycling into two separate processes forces operators to frequently bend over to move materials and disrupts the process, thus affecting overall efficiency.

Method used

Design a multifunctional material preparation device, including a platform component and a recycling component. The platform component is automatically lowered to a suitable operating height by a flexible suspension component. Combined with the recycling component, it realizes continuous operation of unpacking and cardboard recycling, reducing bending over and integrating it into a single process.

Benefits of technology

It significantly reduces the frequency and extent of workers bending over repeatedly, improves overall work efficiency and ergonomics, and integrates unpacking, material preparation and cardboard recycling into continuous operations, thereby enhancing operational convenience and process continuity.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to material preparation technical field. The utility model discloses a kind of multifunctional material preparation device, including device frame, platform component, elastic suspension and recycling component;Platform component is slidably installed on device frame along vertical direction, for placing to be unpacked material box;Elastic suspension one end is installed on device frame, other end is installed on platform component, for as the force support of platform component;Recycling component is slidably installed on device frame along horizontal direction, below platform component, for placing the outer box of unpacked material box. When single or multiple stacked to-be-unpacked material box is placed on the platform component of the scheme, it can automatically descend adjustment to make the work surface of the uppermost to-be-unpacked material box maintain at comfortable height suitable for manual unpacking. While, recycling component below makes that empty outer box produced by unpacking can be collected together immediately and conveniently. It has the advantages of reducing the action frequency and amplitude of staff repeated bending, effectively reduce labor intensity.
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Description

Technical Field

[0001] This utility model relates to the field of material preparation technology, and in particular to a multifunctional material preparation device. Background Technology

[0002] In the material management process of modern manufacturing, unpacking material boxes before production preparation is a high-frequency and labor-intensive basic operation. Especially when faced with large-scale, high-frequency material receiving and unpacking needs, the existing operation mode exposes a series of systemic problems that significantly affect efficiency and human-machine ergonomics.

[0003] Traditional unpacking operations are confined to the warehouse, requiring operators to frequently travel between work sites and simultaneously perform two tasks: material transfer and waste packaging material (mainly cardboard boxes) recycling. This necessitates operating two separate sets of transfer equipment (unpacking material cart and cardboard recycling cart). This not only complicates the workflow but also severely reduces operational convenience and overall efficiency due to the need for personnel to repeatedly drag two sets of equipment.

[0004] In the core unpacking stage, operators need to bend over to place the materials from the material boxes into the empty material bins on the recycling cart. After unpacking, the remaining outer boxes are placed on another recycling cart. Operators must maintain a bent-over posture during unpacking, with frequent and significant bending. After unpacking the material boxes, operators must interrupt the current process to perform a secondary operation: collecting and transporting the scattered waste cardboard boxes to another recycling cart. This cardboard box recycling stage not only further increases labor intensity, but its core movement also primarily involves high-frequency bending and carrying. More significantly, the existing model forcibly separates material unpacking and cardboard recycling into two physically separate processes, resulting in a clear disconnect and discontinuity in the workflow. Operators cannot process packaging waste simultaneously during unpacking; they must switch to recycling operations after completing the unpacking task. This gap in process transition severely restricts the improvement of overall operational efficiency.

[0005] It is evident that the existing unpacking operation mode has fundamental shortcomings in terms of operational efficiency, ergonomics, and process continuity. Utility Model Content

[0006] The purpose of this invention is to provide a multifunctional material preparation device, which aims to solve the fundamental deficiencies of existing unpacking operation modes in terms of operational efficiency, ergonomics, and process continuity.

[0007] To solve the above-mentioned technical problems, the purpose of this utility model is achieved through the following technical solution: providing a multifunctional material preparation device, comprising:

[0008] Device frame;

[0009] The platform component is slidably mounted on the device frame in the vertical direction for placing the material box to be disassembled;

[0010] An elastic suspension element is mounted on the device frame at one end and on the platform assembly at the other end, serving as a load-bearing support for the platform assembly.

[0011] The recycling component is slidably mounted on the device frame in the horizontal direction, located below the platform component, and is used to place the outer box of the disassembled material box;

[0012] The platform component is used to support the material box to be disassembled when it is placed on it, and to lower it to the corresponding height through the elastic suspension member.

[0013] Furthermore, the platform components include:

[0014] The platform frame is slidably mounted on the device frame along the vertical direction on its outer side;

[0015] The support plate is laid horizontally on the platform frame.

[0016] Furthermore, the platform frame includes multiple side rods, multiple load-bearing rods, and multiple platform sliding components;

[0017] The multiple side bars are assembled into a polygonal frame using multiple platform sliding parts as splicing points;

[0018] The plurality of support rods are installed side by side in the polygonal frame and are used to support the support plate;

[0019] The multiple platform sliders are slidably mounted on the device frame in the vertical direction.

[0020] Furthermore, the elastic suspension element includes:

[0021] The first fastener is installed on the device frame;

[0022] The second fastener is installed on the platform component;

[0023] The force-bearing elastic element is connected to the first fastener and the second fastener at both ends, and is used to generate corresponding elastic tensile movement according to the force on the platform frame, so as to support the platform component that moves under force.

[0024] Furthermore, the force-bearing elastic element includes one of an elastic rope and a tension spring.

[0025] Furthermore, the elastic suspension member is provided with multiple locations and connected to multiple outer positions of the recovery assembly.

[0026] Furthermore, the recycling component includes:

[0027] Recycling bins are used to hold the outer boxes of disassembled material containers.

[0028] The recycling slider is slidably mounted on the device frame in a horizontal direction and connected to the recycling frame.

[0029] Furthermore, the recycling slider is a slider fitted onto the device frame, and the slider is provided with a fastening block connected to the recycling frame.

[0030] Furthermore, at least one shelf is provided on the outer side of the device frame.

[0031] Furthermore, the bottom of the device frame is equipped with multiple casters.

[0032] Compared with the prior art, the present invention has at least the following beneficial effects:

[0033] This invention utilizes the automatic descent of the platform component and the elastic support of the flexible suspension components to automatically adjust the working surface of the topmost material box to maintain a comfortable height for manual unpacking, regardless of whether single or multiple stacked material boxes are placed (the increased weight of the stacking will cause the platform component to descend further). This significantly reduces the frequency and extent of workers' repeated bending over, effectively reducing labor intensity. Simultaneously, the recycling component below the platform component allows for the immediate and convenient collection of empty outer boxes generated during unpacking, eliminating the need for workers to turn around or leave their workstations to handle empty boxes. This eliminates the secondary handling of packaging boxes, integrating unpacking, material preparation, and cardboard recycling into a continuous "one-piece flow operation," greatly improving overall operational efficiency.

[0034] The above description is only an overview of the technical solution of this utility model. In order to better understand the technical means of this utility model and to implement it in accordance with the contents of the specification, the preferred embodiments of this utility model are described in detail below with reference to the accompanying drawings. Attached Figure Description

[0035] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0036] Figure 1 A schematic diagram of the overall structure of the multifunctional material preparation device provided in the embodiment of this utility model.

[0037] Figure 2 A schematic diagram of the cooperation structure between the platform component and the elastic suspension component provided in the embodiment of this utility model.

[0038] Figure 3 A schematic diagram of the structure of the recycling component provided in an embodiment of this utility model.

[0039] Figure 4 for Figure 2 A magnified structural diagram of part A in the middle.

[0040] Figure 5 for Figure 2 A magnified structural diagram of part B in the middle.

[0041] Figure 6 for Figure 3 A magnified structural diagram of part C in the middle.

[0042] Explanation of the markings in the image:

[0043] 1. Equipment frame;

[0044] 2. Platform components; 21. Platform frame; 211. Side rod; 212. Support rod; 213. Platform sliding component; 214. Connecting part; 215. Expansion groove; 22. Support plate;

[0045] 3. Elastic suspension component; 31. First fastener; 32. Second fastener; 33. Load-bearing elastic component;

[0046] 4. Recycling components; 41. Recycling frame; 42. Recycling slider; 421. Slider; 422. Fastening block;

[0047] 5. Shelves;

[0048] 6. Casters. Detailed Implementation

[0049] 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, not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.

[0050] It should be understood that, when used in this specification and the appended claims, the terms "comprising" and "including" indicate the presence of the described features, integrals, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more other features, integrals, steps, operations, elements, components and / or collections thereof.

[0051] It should also be understood that the terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the scope of the invention. As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” are intended to include the plural forms unless the context clearly indicates otherwise.

[0052] It should also be further understood that the term "and / or" as used in this specification and the appended claims refers to any combination of one or more of the associated listed items and all possible combinations, and includes such combinations.

[0053] Please see Figures 1 to 3 This utility model embodiment provides a multifunctional material preparation device, including:

[0054] Device frame 1;

[0055] Platform component 2 is slidably mounted on device frame 1 in the vertical direction and is used to place the material box to be disassembled;

[0056] The elastic suspension component 3 is mounted on the device frame 1 at one end and on the platform component 2 at the other end, and is used as a force support for the platform component 2.

[0057] The recycling component 4 is slidably installed on the device frame 1 in the horizontal direction, located below the platform component 2, and is used to place the outer box of the disassembled material box;

[0058] The platform component 2 is used to support the material box to be disassembled when it is placed on it, and lower it to the corresponding height through the elastic suspension component 3.

[0059] In this embodiment, the multi-functional material preparation device can be arranged in the next stage of the transportation equipment. The material boxes to be unpacked can be directly transported to the platform component 2 through the transportation equipment without manual handling, which improves work efficiency.

[0060] In this embodiment, when workers need to unpack and prepare materials, the material box containing the materials is placed on platform component 2. Because platform component 2 bears the weight, it overcomes the initial tension or elasticity of the elastic suspension 3 and slides downwards along the vertical guide structure of the device frame 1 until platform component 2 and the material box on it descend to a specific height. This descending height is determined by the elastic characteristics of the elastic suspension 3 and the weight it bears. Its design goal is to ensure that the unpacking position of the material box (generally the top of the material box) is at a height where workers can comfortably operate with their arms while standing, without excessive bending. Below platform component 2, recycling component 4 is mounted on device frame 1 by horizontal sliding. After workers have unpacked a material box and removed the internal materials, they can easily (e.g., with their feet) hook out recycling component 4 below, place the remaining empty outer box into recycling component 4, and push it back.

[0061] Based on this, this embodiment, through the automatic descent of platform component 2 and the elastic support of elastic suspension component 3, can automatically adjust to maintain the working surface of the topmost material box at a comfortable height suitable for manual unpacking, regardless of whether single or multiple stacked material boxes are placed (the increased weight of the stacking will cause platform component 2 to descend further). This significantly reduces the frequency and extent of workers' repeated bending over, effectively reducing labor intensity. Simultaneously, the recycling component 4 below platform component 2 allows empty outer boxes generated during unpacking to be collected instantly and conveniently, eliminating the need for workers to turn around or leave their workstations to handle empty boxes. This eliminates the secondary turnover of packaging box recycling, integrating unpacking, material preparation, and cardboard recycling into a continuous "one-piece flow operation," greatly improving overall work efficiency and ergonomics.

[0062] In one embodiment, the device frame 1 can be composed of multiple pipe fittings (such as lean pipes) spliced ​​together, wherein there are no pipe fittings on the front and top sides of the device frame 1, and the front side of the device frame 1 serves as the unpacking position for the operator.

[0063] In one embodiment, platform component 2 includes:

[0064] Platform frame 21 is slidably mounted on device frame 1 on its outer side along the vertical direction;

[0065] The support plate 22 is laid horizontally on the platform frame 21.

[0066] In this embodiment, the platform component 2 specifically includes a platform frame 21 and a support plate 22. The platform frame 21 serves as the main frame, and its outer side can be slidably mounted vertically on the corresponding guide rail or column of the device frame 1 via sliding components (such as sliders 421, rollers, etc.), ensuring that the platform frame 21 can only perform smooth up-and-down linear movement. The support plate 22 is laid horizontally on the platform frame 21, forming a support surface for placing the material box to be disassembled; when the material box to be disassembled is placed on the support plate 22, its weight is transferred to the platform frame 21 through the support plate 22, thereby causing the entire platform frame 21 to slide downwards along the device frame 1.

[0067] Based on this, the platform frame 21 in this embodiment provides a rigid support and guiding foundation, ensuring the stability and directionality of the overall movement of the platform component 2; the bearing plate 22 provides a flat and reliable bearing surface, facilitating the placement of material boxes of various sizes. Together, they achieve the functions of stable bearing and precise guided descent.

[0068] In one embodiment, the platform frame 21 includes a plurality of side rods 211, a plurality of support rods 212, and a plurality of platform sliders 213;

[0069] Multiple side bars 211 are assembled into a polygonal frame using multiple platform sliding parts 213 as splicing points;

[0070] Multiple load-bearing rods 212 are installed side by side in the polygonal frame and are used to support the load-bearing plate 22;

[0071] Multiple platform sliders 213 are slidably mounted on the device frame 1 in the vertical direction.

[0072] In this embodiment, the platform frame 21 is assembled from multiple side rods 211, multiple load-bearing rods 212, and multiple platform sliding members 213. The specific assembly process is as follows: the ends of the multiple side rods 211 (typically forming the four sides of a rectangle or square) are connected and fixed to each other through multiple platform sliding members 213 (which have both connecting and sliding functions) as splicing points, thus assembling a stable polygonal frame (typically a rectangular frame). Then, multiple load-bearing rods 212 (as crossbeams) are installed side-by-side and horizontally inside this polygonal frame, spanning two opposite sides of the frame, and the multiple load-bearing rods 212 jointly bear the main load-bearing task. Finally, the load-bearing plate 22 is laid on the side-by-side load-bearing rods 212. The multiple platform sliding members 213 not only serve as splicing points for the frame but also slide vertically on the guide rails or columns of the device frame 1. In this way, the weight of the entire platform frame 21, its load-bearing plate 22, and the material box is ultimately transferred to the guide rails or columns of the device frame 1 through the platform sliding members 213, achieving vertical movement.

[0073] Based on this, in this embodiment, the side rods 211 form the main frame to ensure the overall structural strength, and the load-bearing rods 212 are arranged side by side to provide uniform and powerful direct load-bearing support to the load-bearing plate 22. The platform sliding component 213 integrates the dual functions of frame connection and guiding sliding, making the assembly of the platform frame 21 simpler, the force transmission more direct, and the vertical sliding more reliable and stable.

[0074] Combination Figure 4 As shown, in some embodiments of the platform slider 213, the platform slider 213 is a sliding block with internal rollers. The platform slider 213 is fitted onto the guide rail or column of the device frame 1, or the guide rail or column of the device frame 1 passes through the platform slider 213, and the platform slider 213 slides stably on the guide rail or column of the device frame 1 through its internal rollers. Furthermore, the side of the platform slider 213 is provided with a plug-in part 214, which is used for plugging and assembling the end of the side rod 211. An expansion groove 215 is opened at the plug-in interface of the plug-in part 214 to facilitate a certain elastic deformation when the end of the side rod 211 is plugged in, ensuring that the plug-in is stable and not easy to fall off.

[0075] Combination Figure 5 As shown, in one embodiment, the elastic suspension member 3 includes:

[0076] The first fastener 31 is installed on the device frame 1;

[0077] The second fastener 32 is installed on platform component 2;

[0078] The force-bearing elastic element 33 is connected to the first fastener 31 and the second fastener 32 at both ends, and is used to generate corresponding elastic tensile movement according to the force on the platform frame 21 to support the platform component 2 that is moved by the force.

[0079] In this embodiment, the first fastener 31 (such as a clamping block, hook, connecting ring, etc.) is fixedly installed on the upper part of the device frame 1 (usually higher than the highest position of the platform assembly 2). The second fastener 32 (also a clamping block, hook, connecting ring, etc.) is fixedly installed on the platform assembly 2 (usually the platform frame 21). The two ends of the force-bearing elastic member 33 are firmly connected to the first fastener 31 and the second fastener 32 respectively, so that it is in a pre-stretched or pre-tensioned state. When no material box is placed on the platform assembly 2, the tension or elastic force of the force-bearing elastic member 33 is sufficient to maintain the platform assembly 2 in a higher initial position. When a material box to be removed is placed, the weight of the platform assembly 2 increases and it moves downward. At this time, the force-bearing elastic member 33 is further stretched, generating an upward elastic restoring force that balances the downward gravity of the platform assembly 2. The platform assembly 2 descends until its gravity and the elastic restoring force generated by the force-bearing elastic member 33 reach an equilibrium point, at which point the platform assembly 2 stops descending. The platform height corresponding to this equilibrium point is the suitable operating height. After the material box is unpacked and the materials are removed and the outer box is recycled, the weight is reduced, and the elastic restoring force of the stressed elastic element 33 will cause the platform component 2 to rise back to its initial position.

[0080] Based on this, this embodiment utilizes the elastic deformation characteristics of the stressed elastic element 33 to convert the vertical displacement (descent) of the platform assembly 2 into the tensile deformation of the elastic element. The elastic restoring force dynamically supports platform assemblies 2 of different weights and their loads, achieving adaptive height adjustment. The first fastener 31 and the second fastener 32 provide reliable and easy-to-install and maintain connection points.

[0081] In one embodiment, the force-bearing elastic element 33 includes one of an elastic cord and a tension spring.

[0082] In this embodiment, the specific type of the force-bearing elastic element 33 can be an elastic rope or a tension spring. If an elastic rope (such as a high-elasticity rubber rope or a nylon-coated elastic rope) is used, when the platform assembly 2 is lowered under load, the rope is stretched and elongated, and the internal elastic material generates tension, providing an upward pulling force. If a tension spring (such as a cylindrical helical tension spring) is used, when the platform assembly 2 is lowered under load, the spring is stretched, and its helical structure deforms to generate a linearly increasing restoring force, resisting the descent of the platform assembly 2. Regardless of which type is used, its core function is to generate a reverse elastic restoring force whose magnitude varies with displacement (or weight) when the platform assembly 2 is loaded and lowered.

[0083] Based on this, this embodiment uses an elastic rope to provide a gentler cushioning and non-linear characteristics, potentially at a lower cost; while a tension spring provides more precise, linearly controllable tension, and typically has a longer lifespan and higher reliability. Both effectively achieve the core function of generating corresponding elastic deformation based on the force (weight) applied to platform component 2 to support its movement and achieve a balanced position. The specific choice can be adapted according to the actual scenario; this embodiment does not impose any specific limitations.

[0084] In one embodiment, the elastic suspension 3 is provided with a plurality of locations and connected to a plurality of outer positions of the recovery assembly 4.

[0085] In this embodiment, multiple elastic suspension members 3 are provided (e.g., at the four corners or symmetrical sides of the platform frame 21). Each elastic suspension member 3 is independent; that is, one end of each elastic suspension member 3 is installed at a different position on the upper part of the device frame 1 via its first fastener 31, and the other end is installed at the corresponding outer position of the platform assembly 2 (platform frame 21) via its second fastener 32 (such as the middle of each corner or side). When the material box is placed on the platform assembly 2, the multiple elastic suspension members 3 are stretched simultaneously, sharing the load of the platform and generating a total elastic restoring force to balance the gravity of the platform assembly 2, allowing it to descend smoothly.

[0086] Based on this, this embodiment ensures that the platform component 2 is subjected to more uniform force during loading and descent by distributing multiple elastic suspension components 3 at multiple outer positions of the platform component 2, avoiding excessive force at a single point or tilting or jamming of the platform component 2, which significantly improves the smoothness and stability of the lifting and lowering movement of the platform component 2 and ensures the reliability of the operating height adjustment.

[0087] In one embodiment, the recycling component 4 includes:

[0088] Recycling box 41 is used to place the outer box of the disassembled material box;

[0089] The recycling slider 42 is slidably mounted on the device frame 1 in the horizontal direction and is connected to the recycling frame 41.

[0090] In this embodiment, the recycling box 41 (which can be an open basket or frame) is the actual container used to hold the empty outer boxes left after the materials have been unpacked. The recycling slider 42 (e.g., a slider block or a sliding sleeve) is horizontally mounted on the pipe at the bottom of the device frame 1, and the recycling box 41 is connected to the recycling slider 42. After the worker has finished unpacking, they only need to use their foot to hook out the recycling box 41 located directly below the platform component 2, then place the outer box in the recycling box 41 for temporary storage, and then push the recycling component 4 back to its original position horizontally.

[0091] Based on this, the recycling box 41 directly receives the waste (empty outer box) generated from unpacking. The horizontal sliding connection between the recycling sliding part 42 and the device frame 1 makes it very convenient and effortless to pull out and push back the recycling box in the horizontal direction (especially convenient to operate with feet). The recycling and transfer of empty boxes can be completed without bending over or moving the body significantly, which greatly simplifies the recycling process and improves efficiency. It is a key link in realizing the "unpacking and recycling workflow".

[0092] In one embodiment, the recycling box 41 is assembled into a rectangular frame by multiple connecting rods. The top of the rectangular frame has no connecting rods, forming a top placement opening. The empty outer box is placed into the recycling box 41 from the top. The splicing of the multiple connecting rods can be achieved using a similar insertion method to the aforementioned insertion part 214.

[0093] Combination Figure 6 As shown, in one embodiment, the recycling slider 42 is a slider 421 mounted on the device frame 1, and the slider 421 is provided with a fastening block 422 connected to the recycling frame 41.

[0094] In this embodiment, one specific implementation of the recovery slider 42 is a slider 421 fitted onto the device frame 1. The slider 421 has a hole or groove inside that matches the cross-section of the bottom tube of the device frame 1, so that the slider 421 can be tightly fitted onto the slide rod and slide freely along its length; obviously, the recovery slider 42 can also adopt the same structure as the platform slider 213 to achieve sliding assembly.

[0095] On the outer side of the slider 421 (the side facing the recycling frame 41), a fastening block 422 (which can be a protrusion integral with the slider 421 or a connecting block fixed by screws) is provided. This fastening block 422 can be fixedly clamped to the side of the recycling frame 41. Alternatively, mounting holes or slots can be provided at corresponding positions (such as the side wall) of the recycling frame 41, and the fastening block 422 can be connected and fixed in the mounting holes or slots by screws, clips, or gravity self-locking. In this way, the recycling frame 41 is firmly connected to the slider 421. When the recycling frame 41 is pulled, the slider 421 slides on the tube of the device frame 1, realizing the horizontal movement of the recycling assembly 4.

[0096] Based on this, the slider 421 in this embodiment adopts a set-type structure, which is simple and reliable, with low friction and smooth sliding; the fastening block 422 provides a clear and stable connection point, ensuring that the connection between the recycling frame 41 and the slider is firm and will not loosen during movement, thus ensuring the reliability and durability of the recycling component 4.

[0097] In one embodiment, at least one shelf 5 is provided on the outer side of the device frame 1.

[0098] In this embodiment, at least one additional shelf 5 (such as one or more flat panels, wire mesh baskets, etc.) is provided on the outer side of the device frame 1 (usually on the side or rear of a non-main operating area). This shelf 5 is fixed to the frame structure of the device frame 1. When workers are unpacking and preparing materials, they can temporarily or permanently place or hang the unpacked internal materials (such as parts, tools), commonly used auxiliary tools (such as scissors, gloves), or labels to be used on this shelf 5.

[0099] Based on this, the shelving unit 5 in this embodiment expands the functionality and convenience of the device, providing workers with a nearby, easily accessible storage space for materials and tools, avoiding materials and tools from being scattered on the ground or needing to be frequently retrieved from other areas, further optimizing the workflow, and improving work efficiency and human-machine efficiency.

[0100] In one embodiment, the bottom of the device frame 1 is provided with a plurality of casters 6.

[0101] In this embodiment, multiple casters 6 (swivel casters or casters with brakes) are installed at the bottom of the device frame 1. When it is necessary to move the entire multi-functional material preparation device to different workstations or production lines in the workshop, the operator only needs to release the caster brakes (if braked) to easily push or pull the device frame 1, using the bottom casters 6 to roll on the ground, thereby flexibly moving the entire device (including platform assembly 2, elastic suspension 3, recovery assembly 4, etc.) to the target location. After reaching the target location, the caster brakes can be locked to prevent the device from moving accidentally.

[0102] Based on this, the casters 6 give the entire device a high degree of mobility, enabling the material preparation device to be quickly deployed to different work points according to production needs, facilitating production line layout adjustments or handling temporary tasks, greatly improving the equipment's versatility and site adaptability, and solving the problem of insufficient flexibility of fixed-point equipment.

[0103] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any person skilled in the art can easily conceive of various equivalent modifications or substitutions within the technical scope disclosed in this utility model, and these modifications or substitutions should all be covered within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the scope of the claims.

Claims

1. A multifunctional material preparation device, characterized in that, include: Device frame; The platform component is slidably mounted on the device frame in the vertical direction for placing the material box to be disassembled; An elastic suspension element is mounted on the device frame at one end and on the platform assembly at the other end, serving as a load-bearing support for the platform assembly. The recycling component is slidably mounted on the device frame in the horizontal direction, located below the platform component, and is used to place the outer box of the disassembled material box; The platform component is used to support the material box to be disassembled when it is placed on it, and to lower it to the corresponding height through the elastic suspension member.

2. The multifunctional material preparation device according to claim 1, characterized in that, The platform components include: The platform frame is slidably mounted on the device frame along the vertical direction on its outer side; The support plate is laid horizontally on the platform frame.

3. The multifunctional material preparation device according to claim 2, characterized in that, The platform frame includes multiple side rods, multiple load-bearing rods, and multiple platform sliding components; The multiple side bars are assembled into a polygonal frame using multiple platform sliding parts as splicing points; The plurality of support rods are installed side by side in the polygonal frame and are used to support the support plate; The multiple platform sliders are slidably mounted on the device frame in the vertical direction.

4. The multifunctional material preparation device according to claim 1, characterized in that, The elastic suspension component includes: The first fastener is installed on the device frame; The second fastener is installed on the platform component; The force-bearing elastic element is connected to the first fastener and the second fastener at both ends, and is used to generate corresponding elastic tensile movement according to the force on the platform frame, so as to support the platform component that moves under force.

5. The multifunctional material preparation device according to claim 4, characterized in that, The force-bearing elastic element includes one of an elastic rope and a tension spring.

6. The multifunctional material preparation device according to claim 1, characterized in that, The elastic suspension element is provided in multiple locations and connected to multiple outer positions of the recovery assembly.

7. The multifunctional material preparation device according to claim 1, characterized in that, The recycling component includes: Recycling bins are used to hold the outer boxes of disassembled material containers. The recycling slider is slidably mounted on the device frame in a horizontal direction and connected to the recycling frame.

8. The multifunctional material preparation device according to claim 7, characterized in that, The recycling slider is a slider fitted on the device frame, and the slider is provided with a fastening block that is connected to the recycling frame.

9. The multifunctional material preparation device according to claim 1, characterized in that, At least one shelf is provided on the outside of the device frame.

10. The multifunctional material preparation device according to claim 1, characterized in that, The bottom of the device frame is equipped with multiple casters.