A feeding device with buffering function

By installing a buffer pipe in the feeding device to change the direction of the material, the problem of large material impact force is solved and the safety of the device is improved.

CN224450897UActive Publication Date: 2026-07-03JIANGXI UNIVERSE INTELLIGENT EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGXI UNIVERSE INTELLIGENT EQUIP CO LTD
Filing Date
2025-06-13
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

The existing feeding device has a large impact force on the material during the transfer process, which causes liquid material to splash up, resulting in low safety.

Method used

Design a feeding device with a buffer function. By setting multiple buffer pipes in the material transfer component, the adjacent pipes extend at an angle, and the material continuously changes direction as it passes through, thereby reducing the speed and buffering the impact force of falling.

Benefits of technology

It effectively reduces the impact force when materials enter the feeding part, reduces the possibility of liquid materials splashing, and improves the safety of the feeding device.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application relates to the field of electroplating equipment technology, and more particularly to a feeding device with a buffer function. The feeding device includes a frame, a feeding component, a transfer component, and a material-to-be-fed component. The feeding component is mounted on the frame, and the transfer component is also mounted on the frame. The transfer component includes a transfer port and is used to transfer material from the feeding component to the material-to-be-fed component. The material-to-be-fed component includes a material-to-be-fed frame and a buffer tube. The material-to-be-fed frame is mounted on the frame. Multiple buffer channels are formed within the buffer tube, with adjacent buffer channels connected end-to-end. Both the initial and final buffer channels are connected to the outside. When the transfer component transfers material to the material-to-be-fed frame, the transfer port is located directly above the material-to-be-fed frame. Material from the transfer component enters the material-to-be-fed frame through the multiple buffer channels. The extension directions of adjacent buffer channels form an angle.
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Description

Technical Field

[0001] This application relates to the field of electroplating equipment technology, and in particular to a feeding device with a buffer function. Background Technology

[0002] Electroplating is a process that uses electrolysis to deposit a thin layer of another metal or alloy onto the surface of certain metals. It is a process that uses electrolysis to attach a metal film to the surface of metal or other materials, thereby preventing corrosion, improving wear resistance, conductivity, reflectivity, and enhancing aesthetics.

[0003] The addition of materials in electroplating equipment is achieved through a feeding device. However, in related technologies, when the material transfer component of the feeding device transfers materials to the component to be fed, the materials (such as solids) in the transfer component directly enter the component to be fed through the transfer port. The impact force of the falling materials is large, which causes the materials (such as liquids) in the component to be fed to be splashed up, resulting in low safety of the feeding device. Utility Model Content

[0004] This application provides a feeding device with a buffer function, including a frame, a feeding component, a transfer component, and a feeding component. The feeding component is mounted on the frame; the transfer component is mounted on the frame and includes a transfer port; the transfer component is used to transfer the material in the feeding component to the feeding component, which includes a feeding frame and a buffer tube. The feeding frame is mounted on the frame, and the buffer tube has multiple buffer pipes formed inside. Two adjacent buffer pipes are connected end to end, and both the buffer pipe at the beginning and the buffer pipe at the end are connected to the outside. When the transfer component transfers material to the feeding frame, the transfer port is located directly above the feeding frame, and the material in the transfer component enters the feeding frame through the multiple buffer pipes; the extension directions of two adjacent buffer pipes have an included angle.

[0005] The feeding device with buffer function provided in this application includes a feeding frame and a buffer tube. Multiple buffer pipes are formed within the buffer tube, with adjacent buffer pipes connected end-to-end. Both the buffer pipe at the beginning and end of the buffer tube are connected to the outside. The extension directions of adjacent buffer pipes form an angle. When the transfer component transfers material to the feeding frame, the transfer port is located directly above the feeding frame. At this time, the material in the transfer component enters the feeding frame through multiple buffer pipes. Because the extension directions of adjacent buffer pipes form an angle, the material in the transfer component needs to continuously change direction as it passes through the multiple buffer pipes. During this direction change, the material speed continuously decreases. The material speed passing through the buffer pipe at the end of the buffer tube is less than the material speed passing through the buffer pipe at the beginning of the buffer tube, thereby reducing the impact force of the material (such as liquid) entering the feeding frame and reducing the possibility of material (such as solid) splashing within the feeding frame. This improves the safety performance of the feeding device with buffer function. Compared to related technologies where materials (such as solids) in the transfer component directly enter the feeding component through the transfer port, resulting in a large impact force from the falling material and splashing of materials (such as liquids) in the feeding component, which poses a safety hazard, the feeding device with buffering function provided in this application can buffer the impact force of falling material, thereby improving the safety of the feeding device with buffering function.

[0006] In one possible implementation provided in this application, a first buffer pipe and a second buffer pipe are formed inside the buffer material pipe. The first buffer pipe and the second buffer pipe are connected and both are connected to the outside. The material in the transfer component enters the feeding frame through the first buffer pipe and the second buffer pipe. The extension direction of the first buffer pipe is perpendicular to the extension direction of the second buffer pipe.

[0007] In one possible implementation provided in this application, the extension direction of the first buffer pipe is perpendicular to the setting direction of the transfer port and the loading frame, and the extension direction of the second buffer pipe is parallel to the setting direction of the transfer port and the loading frame. The first buffer pipe is provided with a first opening, which is connected to the outside and faces the transfer port. The second buffer pipe is provided with a second opening, which is connected to the outside and faces the loading frame.

[0008] In one possible implementation provided in this application, the second buffer pipe extends into the material-to-be-added frame.

[0009] In one possible implementation provided in this application, the diameter of the first buffer pipe is larger than the diameter of the second buffer pipe, and / or, the diameter of the first buffer pipe closer to the transfer port is larger than the diameter of the first buffer pipe farther from the transfer port.

[0010] In one possible implementation provided in this application, the component to be fed further includes a sliding structure, which is disposed between the feeding frame and the buffer tube. The sliding structure is used to drive the buffer tube to the target position of the feeding frame.

[0011] In one possible implementation provided in this application, the sliding structure includes a sliding track disposed on the feeding frame and a sliding wheel disposed on the buffer tube, the sliding wheel being adapted to the sliding track.

[0012] In one possible implementation provided in this application, the feeding component further includes a feeding frame and a vibrating element. The vibrating element is disposed on the feeding frame and is used to vibrate the feeding frame. When the feeding component transfers material to the transfer component, the feeding frame is connected to the transfer component.

[0013] In one possible implementation provided in this application, the feeding component further includes a telescopic tube, which forms a feeding pipe with both ends open. The first end of the telescopic tube is connected to the feeding frame. When the feeding component transfers material to the transferring component, the second end of the telescopic tube can extend and shorten relative to the transferring component so that the second end of the telescopic tube is connected to the transferring component.

[0014] In one possible implementation provided in this application, a feeding device with a buffer function further includes a weighing component, which is mounted on a frame. When the feeding component transfers material to the transfer component, the weighing component is used to weigh the weight of the material in the transfer component. Attached Figure Description

[0015] Figure 1 A first-view structural schematic diagram of a feeding device with a buffer function provided in an embodiment of this application;

[0016] Figure 2 A second-view structural schematic diagram of a feeding device with a buffer function provided in an embodiment of this application;

[0017] Figure 3 A third-view structural schematic diagram of a feeding device with a buffer function provided in an embodiment of this application;

[0018] Figure 4 Provided for the embodiments of this application Figure 1 Enlarged view of point A in the middle;

[0019] Figure 5 Provided for the embodiments of this application Figure 2 Enlarged view of point B in the middle;

[0020] Figure 6 Provided for the embodiments of this application Figure 3 Enlarged view of point C in the middle;

[0021] Figure 7 A schematic diagram of the structure of the first adapter provided in the embodiments of this application.

[0022] Figure label:

[0023] 1-Feeding device; 11-Frame; 12-Feeding component; 121-Feeding frame; 122-Telescopic pipe; 123-Control component; 13-Transfer component; 131-Final transfer frame; 1311-Transfer port; 132-Intermediate transfer frame; 1321-Intermediate transfer port; 133-Second adapter; 134-Drive plate; 14-Component to be fed; 141-Frame to be fed; 1411-Sliding track; 142-Buffer pipe; 1421-First buffer pipe; 1422-Second buffer pipe; 1423-Sliding wheel; 15-Weighing component; 16-First adapter. Detailed Implementation

[0024] It should be noted that, unless otherwise specified, the embodiments and technical features in the embodiments of this application can be combined with each other, and the detailed descriptions in the specific implementation should be understood as explanations of the purpose of this application and should not be regarded as undue limitations on this application.

[0025] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the specific technical solutions of this application will be further described in detail below with reference to the accompanying drawings of the embodiments of this application. The following embodiments are used to illustrate this application, but are not intended to limit the scope of this application.

[0026] In the embodiments of this application, the terms "first," "second," "third," and "fourth" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Therefore, a feature defined as "first," "second," or "third" may explicitly or implicitly include one or more of that feature. In the description of the embodiments of this application, unless otherwise stated, "multiple" means two or more.

[0027] Furthermore, in the embodiments of this application, directional terms such as "upper," "lower," "left," and "right" are defined relative to the positions in which the components are schematically placed in the accompanying drawings. It should be understood that these directional terms are relative concepts, used for relative description and clarification, and can change accordingly depending on the position of the components in the accompanying drawings.

[0028] In the embodiments of this application, unless otherwise explicitly specified and limited, the term "connection" should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral part; it can be a direct connection or an indirect connection through an intermediate medium.

[0029] In embodiments of this application, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes that element.

[0030] In the embodiments of this application, the terms "exemplary" or "for example" are used to indicate that something is an example, illustration, or description. Any embodiment or design that is described as "exemplary" or "for example" in the embodiments of this application should not be construed as being more preferred or advantageous than other embodiments or design. Specifically, the use of the terms "exemplary" or "for example" is intended to present the relevant concepts in a specific manner.

[0031] Electroplating is a process that uses electrolysis to deposit a thin layer of another metal or alloy onto the surface of certain metals. It utilizes electrolysis to coat the surface of metals or other materials with a metallic film, thereby providing benefits such as corrosion prevention, improved wear resistance, electrical conductivity, reflectivity, and enhanced aesthetics. The addition of materials to the electroplating equipment is achieved through a feeding device.

[0032] Therefore, referring to Figure 1 , Figure 2 and Figure 3 This application provides a feeding device 1 with a buffer function, including a frame 11, a feeding component 12, a transfer component 13, and a feeding component 14. The feeding component 12 is mounted on the frame 11; the transfer component 13 is mounted on the frame 11 and includes a transfer port 1311; the transfer component 13 is used to transfer the material in the feeding component 12 to the feeding component 14. The feeding component 14 includes a feeding frame 141 and a buffer material pipe 142. 141 is mounted on the frame 11. Multiple buffer pipes are formed inside the buffer material pipe 142. Two adjacent buffer pipes are connected end to end. Both the buffer pipe at the beginning and the buffer pipe at the end are connected to the outside. When the material transfer component 13 transfers material to the feeding frame 141, the material transfer port 1311 is located directly above the feeding frame 141. The material in the material transfer component 13 enters the feeding frame 141 through multiple buffer pipes. The extension directions of two adjacent buffer pipes have an included angle.

[0033] In this embodiment, a feeding device 1 with a buffer function includes a frame 11, a feeding component 12, and a component to be fed 14. The feeding component 12 holds one type of material to be added to the component to be fed 14, while the component to be fed 14 holds another type of material. A transfer component 13 transfers the material from the feeding component 12 to the component to be fed 14, allowing the two materials to mix. In one possible implementation provided in this embodiment, the component to be fed 14 holds liquid materials, such as medicine; the feeding component 12 holds solid materials, such as powder; and the transfer component 13 transfers the powder to the component to be fed 14, causing the powder to dissolve in the medicine.

[0034] In this embodiment, the feeding component 12 is disposed on the frame 11. Here, the feeding component 12 can be non-removably disposed on the frame 11, for example, the feeding component 12 can be directly welded to the frame 11, or the feeding component 12 can be directly bonded to the frame 11; of course, the feeding component 12 can also be detachably disposed on the frame 11, for example, the feeding component 12 can be directly snapped onto the frame 11, or the feeding component 12 can be directly screwed onto the frame 11; in this embodiment, there is no limitation on this.

[0035] In this embodiment, the material transfer component 13 is disposed on the frame 11. The material transfer component 13 includes a material transfer port 1311. The material transfer component 13 is used to transfer the material in the feeding component 12 to the material to be fed component 14. Here, the material transfer component 13 can slide relative to the frame 11 between the feeding component 12 and the material to be fed component 14. Of course, the material transfer component 13 can roll relative to the frame 11 between the feeding component 12 and the material to be fed component 14. It should be noted that this embodiment does not limit the movement mode of the material transfer component 13 relative to the frame 11 between the feeding component 12 and the material to be fed component 14.

[0036] In this embodiment, the feeding component 14 includes a feeding frame 141, which is disposed on the frame 11. Here, the feeding frame 141 can be non-removably disposed on the frame 11, for example, the feeding frame 141 can be directly welded to the frame 11, or for example, the feeding frame 141 can be directly glued to the frame 11; of course, the feeding frame 141 can also be detachably disposed on the frame 11, for example, the feeding frame 141 can be directly snapped onto the frame 11, or for example, the feeding frame 141 can be directly screwed onto the frame 11; in this respect, this embodiment does not limit the scope.

[0037] In this embodiment, multiple buffer pipes are formed inside the buffer tube 142. Two adjacent buffer pipes are connected end to end. Both the buffer pipe at the beginning and the buffer pipe at the end are connected to the outside. Here, two buffer pipes can be formed inside the buffer tube 142. Of course, three or more buffer pipes can also be formed inside the buffer tube 142. It should be noted that this embodiment does not limit the number of buffer pipes formed inside the buffer tube 142.

[0038] In this embodiment of the application, when the material transfer component 13 transfers material to the material loading frame 141, the material transfer port 1311 is located directly above the material loading frame 141. Here, it should be explained that the material transfer port 1311 being located directly above the material loading frame 141 means that the material in the material transfer component 13 can directly enter the material loading frame 141 through the material transfer port 1311; or, along the setting direction of the material transfer port 1311 and the material loading frame 141, the material transfer port 1311 falls into the projection within the material loading frame 141.

[0039] In this embodiment, the extension directions of two adjacent buffer pipes have an included angle. Here, the included angle of the extension directions of two adjacent buffer pipes can be an acute angle, for example, 30 degrees, or for example, 60 degrees; the included angle of the extension directions of two adjacent buffer pipes can be a right angle, in other words, 90 degrees; of course, the included angle of the extension directions of two adjacent buffer pipes can be an obtuse angle, for example, 120 degrees, or for example, 150 degrees; it should be noted that this embodiment does not limit the size of the included angle of the extension directions of two adjacent buffer pipes.

[0040] The feeding device 1 with buffer function provided in this application embodiment includes a feeding component 14 comprising a feeding frame 141 and a buffer tube 142. Multiple buffer pipes are formed within the buffer tube 142, with adjacent buffer pipes connected end-to-end. Both the buffer pipe at the beginning and the buffer pipe at the end are connected to the outside, and the extension directions of adjacent buffer pipes form an angle. When the transfer component 13 transfers material to the feeding frame 141, the transfer port 1311 is located directly above the feeding frame 141. At this time, the material in the transfer component 13 enters the feeding frame 141 through the multiple buffer pipes. The feeding frame 141 has an angle between the extension directions of two adjacent buffer pipes. In other words, the material in the transfer component 13 needs to change direction continuously when passing through multiple buffer pipes. During the direction change, the speed of the material continuously decreases. The speed of the material when passing through the buffer pipe at the tail end is less than the speed of the material when passing through the buffer pipe at the head end, thereby reducing the impact force of the material (such as liquid) entering the feeding frame 141. The possibility of the material (such as solid) in the feeding frame 141 splashing is reduced, thereby improving the safety performance of the feeding device 1 with buffer function.

[0041] Compared to related technologies, where materials (such as solids) in the transfer component 13 directly enter the feeding component 14 through the transfer port 1311, the impact force of the falling materials is relatively large, causing materials (such as liquids) in the feeding component 14 to be splashed, resulting in low safety, the feeding device 1 with buffer function provided in this application can buffer the impact force of falling materials, thus improving the safety of the feeding device 1 with buffer function.

[0042] Reference Figure 4 and Figure 5 This application provides a feeding device 1 with a buffer function. A first buffer pipe 1421 and a second buffer pipe 1422 are formed in the buffer pipe 142. The first buffer pipe 1421 and the second buffer pipe 1422 are connected and both are connected to the outside. The material in the transfer component 13 enters the feeding frame 141 through the first buffer pipe 1421 and the second buffer pipe 1422. The extension direction of the first buffer pipe 1421 is perpendicular to the extension direction of the second buffer pipe 1422.

[0043] In this embodiment, the extension direction of the first buffer pipe 1421 can be perpendicular to the setting direction of the transfer port 1311 and the feeding frame 141, and the extension direction of the second buffer pipe 1422 can be parallel to the setting direction of the transfer port 1311 and the feeding frame 141. Alternatively, the extension direction of the first buffer pipe 1421 can be parallel to the setting direction of the transfer port 1311 and the feeding frame 141, and the extension direction of the second buffer pipe 1422 can be perpendicular to the setting direction of the transfer port 1311 and the feeding frame 141. It should be noted that this embodiment does not limit the extension directions of the first buffer pipe 1421 and the second buffer pipe 1422 to the setting direction of the transfer port 1311 and the feeding frame 141.

[0044] The feeding device 1 with buffering function provided in this application embodiment has a first buffer pipe 1421 and a second buffer pipe 1422 formed inside the buffer pipe 142, and the extension direction of the first buffer pipe 1421 is perpendicular to the extension direction of the second buffer pipe 1422. In other words, the buffer pipe 142 is similar to an "L" shape. In this way, the structure of the buffer pipe 142 can be further simplified on the basis of being able to buffer the impact force of falling materials, so that the feeding device 1 with buffering function has the technical effect of simple structure and easy processing.

[0045] Reference Figure 4 and Figure 5This application provides a feeding device 1 with a buffer function. The extension direction of the first buffer pipe 1421 is perpendicular to the setting direction of the transfer port 1311 and the feeding frame 141. The extension direction of the second buffer pipe 1422 is parallel to the setting direction of the transfer port 1311 and the feeding frame 141. The first buffer pipe 1421 is provided with a first opening, which is connected to the outside through the first opening and faces the transfer port 1311. The second buffer pipe 1422 is provided with a second opening, which is connected to the outside through the second opening and faces the feeding frame 141.

[0046] The feeding device 1 with buffer function provided in this application embodiment has a first buffer pipe 1421 extending in a direction perpendicular to the setting direction of the transfer port 1311 and the feeding frame 141, and a second buffer pipe 1422 extending in a direction parallel to the setting direction of the transfer port 1311 and the feeding frame 141. The material flowing out of the transfer port 1311 first enters the first buffer pipe 1421, further decelerating the material. After deceleration, it then passes through the second buffer pipe 1422 and enters the feeding frame 141 from the second buffer pipe 1422, reducing the phenomenon of poor impact force of buffered material caused by insufficient setting position of the buffer pipe 142.

[0047] Reference Figure 4 and Figure 5 This application provides a feeding device 1 with a buffer function, wherein the second buffer pipe 1422 extends into the feeding frame 141.

[0048] The feeding device 1 with a buffer function provided in this application shortens the distance between the second buffer pipe 1422 and the material contained in the feeding frame 141 by extending the second buffer pipe 1422 into the feeding frame 141. This reduces the buffering force of the material passing through the second buffer pipe 1422, preventing the material in the feeding frame 141 from splashing up when it falls into the feeding frame 141, thus avoiding increased danger. In one possible implementation provided in this application embodiment, the second buffer pipe 142 extends into the feeding frame 141, and during feeding, the second buffer pipe 142 can extend into the surface of the material contained in the feeding frame 141 or into the interior of the material.

[0049] Reference Figure 4 and Figure 5 This application provides a feeding device 1 with a buffer function, wherein the diameter of the first buffer pipe 1421 is larger than the diameter of the second buffer pipe 1422, and / or the diameter of the first buffer pipe 1421 near the transfer port 1311 is larger than the diameter of the first buffer pipe 1421 away from the transfer port 1311.

[0050] In this embodiment, the diameter of the first buffer pipe 1421 is greater than the diameter of the second buffer pipe 1422, and / or, the diameter of the first buffer pipe 1421 near the transfer port 1311 is greater than the diameter of the first buffer pipe 1421 away from the transfer port 1311. Here, it can be that the diameter of the first buffer pipe 1421 is greater than the diameter of the second buffer pipe 1422, and the diameter of the first buffer pipe 1421 near the transfer port 1311 is greater than the diameter of the first buffer pipe 1421 away from the transfer port 1311; it can also be that the diameter of the first buffer pipe 1421 near the transfer port 1311 is greater than the diameter of the second buffer pipe 1422, or the diameter of the first buffer pipe 1421 near the transfer port 1311 is greater than the diameter of the first buffer pipe 1421 away from the transfer port 1311.

[0051] The feeding device 1 with buffering function provided in this application embodiment has a larger diameter for the first buffer pipe 1421 than for the second buffer pipe 1422, and / or, a larger diameter for the first buffer pipe 1421 near the transfer port 1311 than for the first buffer pipe 1421 away from the transfer port 1311. In other words, the capacity of the first buffer pipe 1421 is greater than the capacity of the second buffer pipe 1422, or the capacity of the first buffer pipe 1421 near the transfer port 1311 is greater than the capacity of the first buffer pipe 1421 away from the transfer port 1311. In this way, the speed at which material enters the first buffer pipe 1421 through the transfer port 1311 can be increased.

[0052] Reference Figure 4 and Figure 5 This application provides a feeding device 1 with a buffer function. The feeding component 14 also includes a sliding structure. The sliding structure is disposed between the feeding frame 141 and the buffer tube 142. The sliding structure is used to drive the buffer tube 142 to the target position of the feeding frame 141.

[0053] In this embodiment, the sliding structure can be a sliding guide rail disposed on the feeding frame 141 and a sliding protrusion disposed on the buffer material tube 142, with the sliding guide rail and the sliding protrusion being adapted to each other; alternatively, the sliding structure can also be a sliding protrusion disposed on the feeding frame 141 and a sliding guide rail disposed on the buffer material tube 142, with the sliding guide rail and the sliding protrusion being adapted to each other. It should be noted that this embodiment does not limit the specific structure of the sliding structure. Of course, the sliding structure can also be a rolling structure, etc., as long as it can drive the buffer material tube 142 to the target position of the feeding frame 141.

[0054] The feeding device 1 with buffer function provided in this application embodiment has a sliding structure between the feeding frame 141 and the buffer tube 142. The sliding structure can drive the buffer tube 142 to the target position of the feeding frame 141. In other words, the sliding structure can drive the buffer tube 142 to any position of the feeding frame 141. In this way, the material in the buffer tube 142 can be prevented from piling up in the feeding frame 141, thereby increasing the contact area between the material in the buffer tube 142 and the material in the feeding frame 141.

[0055] Reference Figure 4 and Figure 5 This application provides a feeding device 1 with a buffer function. The sliding structure includes a sliding track 1411 disposed on the feeding frame 141 and a sliding wheel 1423 disposed on the buffer material tube 142. The sliding wheel 1423 is adapted to the sliding track 1411.

[0056] The feeding device 1 with buffer function provided in this application embodiment has a sliding structure including a sliding track 1411 set on the feeding frame 141 and a sliding wheel 1423 set on the buffer material tube 142. The sliding wheel 1423 is adapted to the sliding track 1411, thus having the technical effect of simple structure and easy implementation.

[0057] Reference Figure 6 This application provides a feeding device 1 with a buffer function. The feeding component 12 also includes a feeding frame 121 and a vibrating element. The vibrating element is disposed on the feeding frame 121 and is used to vibrate the feeding frame 121. When the feeding component 12 transfers material to the material transfer component 13, the feeding frame 121 is connected to the material transfer component 13.

[0058] In this embodiment, a vibrator is disposed on the feeding frame 121 to vibrate the feeding frame 121. The vibrator can be disposed outside the feeding frame 121 or inside the feeding frame 121; this embodiment does not limit the vibrator's placement. In one possible implementation provided by this embodiment, the vibrator is disposed outside the feeding frame 121 to reduce the possibility of contaminating the material in the feeding frame 121.

[0059] In this embodiment, a vibrator is disposed on the feeding frame 121 to vibrate the feeding frame 121. Here, the vibrator can be disposed on the feeding frame 121 in a non-removable manner, for example, the vibrator is welded to the feeding frame 121, or the vibrator is glued to the feeding frame 121. Of course, the vibrator can also be disposed on the feeding frame 121 in a detachable manner, for example, the vibrator is snapped onto the feeding frame 121, or the vibrator is screwed onto the feeding frame 121. It should be noted that this embodiment does not limit the specific manner in which the vibrator is disposed on the feeding frame 121.

[0060] In this embodiment, a vibrator is disposed on the feeding frame 121 to vibrate the feeding frame 121. Here, the vibrator can vibrate the feeding frame 121 in a linear vibration, a rotational vibration, or a combined vibration. It should be noted that this embodiment does not limit the vibration mode of the vibrator on the feeding frame 121.

[0061] The feeding device 1 with buffer function provided in this application embodiment is provided with a vibrating element, which is then placed on the feeding frame 121 to vibrate the feeding frame 121 and prevent the feeding frame 121 from jamming.

[0062] Reference Figure 6 This application provides a feeding device 1 with a buffer function. The feeding component 12 also includes a telescopic tube 122. A feeding pipe is formed inside the telescopic tube 122. Both ends of the feeding pipe are open. The first end of the telescopic tube 122 is connected to the feeding frame 121. When the feeding component 12 transfers material to the material transfer component 13, the second end of the telescopic tube 122 can be extended and shortened relative to the material transfer component 13 so that the second end of the telescopic tube 122 is connected to the material transfer component 13.

[0063] The feeding device 1 with buffer function provided in this application embodiment, by setting a telescopic tube 122, when the feeding component 12 transfers material to the transferring component 13, the second end of the telescopic tube 122 can be extended and shortened relative to the transferring component 13 so that the second end of the telescopic tube 122 is connected to the transferring component 13, and the feeding frame 121 is connected to the transferring component 13 through the telescopic tube 122, so as to reduce the processing and assembly difficulty of directly connecting the feeding frame 121 and the transferring component 13.

[0064] Reference Figure 6 This application embodiment also provides a feeding device 1 with a buffer function. The feeding component 12 further includes a control component 123, which is disposed between the telescopic tube 122 and the feeding frame 121 to control the communication between the second end of the telescopic tube 122 and the material transfer component 13.

[0065] Reference Figure 1 , Figure 2and Figure 3 This application provides a feeding device 1 with a buffer function, and also includes a weighing component 15. The weighing component 15 is disposed on the frame 11. When the feeding component 12 transfers material to the transfer component 13, the weighing component 15 is used to weigh the weight of the material in the transfer component 13.

[0066] In this embodiment of the application, the weighing component 15 is used to weigh the material in the transfer component 13. Here, the weighing component 15 can be a mechanical lever scale; the weighing component 15 can also be a deformation sensing scale; the weighing component 15 can also be an electromechanical hybrid scale; the weighing component 15 can also be an industrial sensor scale. It should be noted that this embodiment of the application does not limit the specific type of the weighing component 15.

[0067] The feeding device 1 with buffer function provided in this application embodiment, when the feeding component 12 transfers material to the transfer component 13, the weighing component 15 is used to weigh the weight of the material in the transfer component 13. In this way, quantitative addition can be achieved, adding only what is consumed, which can improve the electroplating effect and quality.

[0068] Reference Figure 1 , Figure 2 , Figure 3 as well as Figure 7 This application embodiment also provides a feeding device 1 with a buffer function, which further includes a driving component. The driving component is disposed on the frame 11 and includes a driving plate 134. The driving plate 134 moves relative to the frame 11 between the feeding component 12 and the component to be fed 14. The material transfer component 13 includes a final transfer frame 131, an intermediate transfer frame 132, and a second adapter 133 disposed on the intermediate transfer frame 132. The final transfer frame 131 includes a transfer port 1311, and the intermediate transfer frame 132 includes an intermediate transfer port 1321. The frame 132 is movably mounted on the drive plate 134. When the drive plate 134 drives the intermediate transfer frame 132 to move to the feeding component 14, the second adapter 133 abuts against the first adapter 16, and the drive plate 134 pushes the second adapter 133 to rotate relative to the first adapter 16, so that the side of the intermediate transfer frame 132 with the intermediate transfer port 1321 flips towards the side of the final transfer frame 131. In this way, the material in the intermediate transfer frame 132 can enter the final transfer frame 131 through the intermediate transfer port 1321.

[0069] Additionally, refer to Figure 1 , Figure 2 , Figure 3 as well as Figure 7This application also provides the working process of a feeding device 1 with a buffer function. Specifically, in the feeding device 1 with a buffer function, the feeding frame 121 in the feeding component 12 stores material. Then, the control component 123 in the feeding component 12 controls the material in the feeding frame 121 to enter the transfer frame 132. Next, the weighing component 15 weighs the weight of the material in the transfer frame 132 and transmits the data to the main control of the feeding device 1 with a buffer function. After the transfer frame 132 is filled, the driving component drives the transfer frame 132 to stop. At material component 14, immediately afterward, under the action of drive plate 134, first adapter 16 and second adapter 133, the transfer frame 132 with the transfer port 1321 is flipped toward the final transfer frame 131, and the material in the transfer frame 132 can enter the final transfer frame 131 through the transfer port 1321; finally, the material in the final transfer frame 131 is added to any position of the loading frame 141 through the transfer port 1311, the buffer pipe and the sliding structure set between the buffer pipe and the loading frame 141.

[0070] Furthermore, in the feeding device 1 with buffer function, the feeding frame 121 in the feeding component 12 stores the material. To prevent material blockage, a vibrator is provided on the feeding frame 121. The material in the feeding frame 121 is controlled by the control component 123 to enter the feeding pipe. The second end of the telescopic tube 122 can be extended and shortened relative to the transfer component 13 so that the second end of the telescopic tube 122 is connected to the transfer frame 132.

[0071] Furthermore, in the feeding device 1 with buffer function, the transfer frame 132 is placed on the weighing component 15, and the weighing shut-off control component 123 is used. After the weighing is completed, the second end of the telescopic tube 122 is disconnected from the transfer frame 132.

[0072] Furthermore, in the feeding device 1 with buffer function, during the process of the intermediate transfer frame 132 moving from the feeding component 12 to the feeding component 14, under the combined action of the driving component, the first adapter 16 and the second adapter 133, the side of the intermediate transfer frame 132 with the intermediate transfer port 1321 flips towards the final transfer frame 131, and the material in the intermediate transfer frame 132 can enter the final transfer frame 131 through the intermediate transfer frame 132; finally, the material in the final transfer frame 131 enters any position in the feeding frame 141 through the transfer port 1311, the first buffer pipe 1421, the second buffer pipe 1422 and the sliding structure.

[0073] The sequence numbers of the embodiments in this application are for descriptive purposes only and do not represent the superiority or inferiority of the embodiments. The above are merely preferred embodiments of this application and do not limit the patent scope of this application. Any equivalent structural or procedural transformations made based on the content of this application's specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this application.

Claims

1. A feeding device having a buffering function, characterized by comprising: include: frame; A feeding component is mounted on the frame; A material transfer component is disposed on the frame, and the material transfer component includes a material transfer port; The material-to-feed component includes a material-to-feed frame and a buffer tube. The material-to-feed frame is mounted on the frame. The buffer tube contains multiple buffer pipes, with adjacent buffer pipes connected end-to-end. Both the buffer pipe at the beginning and the buffer pipe at the end are connected to the outside. When the material-to-feed component transfers the material to the material-to-feed frame, the transfer port is located directly above the material-to-feed frame. The material in the material-to-feed component enters the material-to-feed frame through the multiple buffer pipes. The two adjacent buffer pipes extend at an angle to each other.

2. The feeding device with a buffering function according to claim 1, characterized in that, The buffer tube has a first buffer pipe and a second buffer pipe, which are connected to each other and both are connected to the outside. The material in the material transfer component enters the feeding frame through the first buffer pipe and the second buffer pipe. The extension direction of the first buffer pipe is perpendicular to the extension direction of the second buffer pipe.

3. The feeding device with a buffering function according to claim 2, wherein, The first buffer pipe extends perpendicularly to the orientation of the transfer port and the loading frame, and the second buffer pipe extends parallel to the orientation of the transfer port and the loading frame. The first buffer pipe has a first opening that connects to the outside and faces the transfer port. The second buffer pipe has a second opening that connects to the outside and faces the loading frame.

4. The feeding device with a buffering function according to claim 3, wherein The second buffer pipe extends into the feed box.

5. The feeding device with a buffering function according to claim 2, wherein The diameter of the first buffer pipe is larger than the diameter of the second buffer pipe, and / or the diameter of the first buffer pipe closer to the transfer port is larger than the diameter of the first buffer pipe farther from the transfer port.

6. The charging device with a buffering function according to any one of claims 1 to 5, characterized in that, The component to be fed also includes a sliding structure, which is disposed between the feeding frame and the buffer tube. The sliding structure is used to drive the buffer tube to the target position of the feeding frame.

7. The feeding device with a buffering function according to claim 6, wherein The sliding structure includes a sliding track disposed on the feeding frame and a sliding wheel disposed on the buffer tube, the sliding wheel being adapted to the sliding track.

8. The feeding device with a buffering function according to any one of claims 1 to 5, characterized in that, The feeding component also includes a feeding frame and a vibrating element. The vibrating element is disposed on the feeding frame and is used to vibrate the feeding frame. When the feeding component transfers material to the transferring component, the feeding frame is in communication with the transferring component.

9. The feeding device with a buffering function according to claim 8, wherein, The feeding component also includes a telescopic tube, which forms a feeding pipe. Both ends of the feeding pipe are open. The first end of the telescopic tube is connected to the feeding frame. When the feeding component transfers material to the transferring component, the second end of the telescopic tube can extend and shorten relative to the transferring component so that the second end of the telescopic tube is connected to the transferring component.

10. The charging device with a buffering function according to any one of claims 1 to 5, characterized in that, The feeding device also includes a weighing component, which is mounted on the frame. When the feeding component transfers material to the transfer component, the weighing component is used to weigh the material inside the transfer component.