A rotary feeding device

By designing the transfer mechanism and rotary components of the rotary feeding device, automatic alternating position switching of fully loaded container facilities is realized, solving the problem of waiting for empty facilities during the feeding process in the existing technology and improving work efficiency.

CN224376066UActive Publication Date: 2026-06-19JIANGSU SIYANG XIELI LIGHT IND MASCH CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU SIYANG XIELI LIGHT IND MASCH CO LTD
Filing Date
2025-07-15
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In the current material feeding process, after a fully loaded container is transferred to the next process, it must wait for an empty container to be placed, resulting in a waste of time and resources and low work efficiency.

Method used

Design a rotary feeding device that drives the support component to rotate and move through the transfer mechanism and rotary component, realizes the alternating switching of the position of the mobile platform, and automatically places the empty facility when the fully loaded container leaves. The device utilizes the coordinated work of the rotary power source and the moving power component to achieve automatic alternation of the container position.

Benefits of technology

It saves time and resources in the feeding process, improves work efficiency, and avoids waiting for the intervention of operators or other structures.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application relates to a rotary feeding device, including a frame with a transfer mechanism on the frame. The transfer mechanism is used to transfer containerized facilities. The transfer mechanism includes a support component and a rotary component. The rotary component drives the support component to rotate and move, and the support component drives the containerized facilities to move. The support component includes a first moving platform and a second moving platform, which are used to alternately drive fully loaded or empty containerized facilities to move. This application has the advantage that the feeding device can place empty containerized facilities at the containerized position when transferring materials, thus saving time and resources in the feeding process and improving work efficiency.
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Description

Technical Field

[0001] This application relates to the technical field of material conveying, and in particular to a rotary feeding device. Background Technology

[0002] When transferring materials, it is usually necessary to move the fully loaded container from the container location to the next process, and then wait for the operator or other structure to put the empty container back in the container location before the material collection can continue. This results in a waste of time and resources in the material feeding process, thus making the work efficiency low. Utility Model Content

[0003] In view of the shortcomings of the existing technology, one of the purposes of this application is to provide a rotary feeding device, which has the advantage of placing an empty container at the container position when transferring materials, thereby saving time and resources in the feeding process and thus improving work efficiency.

[0004] The above-mentioned objective of this application is achieved through the following technical solution:

[0005] A rotary feeding device includes a frame with a transfer mechanism on the frame for transferring container facilities. The transfer mechanism includes a support component and a rotary component. The rotary component drives the support component to rotate and move, and the support component drives the container facilities to move. The support component includes a first mobile platform and a second mobile platform, which are used to alternately drive fully loaded or unloaded container facilities to move.

[0006] By adopting the above technical solution, the rotary component drives the support component to rotate and move, so that the positions of the first mobile platform and the second mobile platform can be switched alternately. This allows the support component to place the empty container at the container position when it carries the fully loaded container away from the container position, without waiting for other structures or operators to intervene. This saves time and resources in the feeding process, thus making the work more efficient.

[0007] In a preferred embodiment, this application may be further configured to include a conveying mechanism one and a conveying mechanism two, wherein the conveying mechanism one is used to receive a fully loaded container on the transfer mechanism and move it, and the conveying mechanism two is used to transfer an empty container to the transfer mechanism.

[0008] In a preferred embodiment, the present application may be further configured such that: the rotary component includes a rotary power source and a moving power component, the support component is connected to the rotary power source, the rotary power source is used to drive the support component to rotate, and the moving power component is used to drive the rotary power source to move.

[0009] By adopting the above technical solution, the rotational power source drives the support component to rotate, thereby enabling the alternating switching of the positions of the first and second mobile platforms. The mobile power component drives the rotational power source to move, allowing the support component to move.

[0010] In a preferred embodiment, this application can be further configured such that the moving power component includes a lateral movement source and a vertical movement source, wherein the lateral movement source is used to drive the support component to move laterally, and the vertical movement source is used to drive the support component to move vertically.

[0011] By adopting the above technical solution, the vertical moving source drives the support component to move vertically, so that the container on the support component is placed at the container point. The horizontal moving source and the vertical moving source work together to achieve the purpose of moving the support component within a suitable range.

[0012] In a preferred embodiment, this application may be further configured such that: the moving power component includes a mounting bracket for sliding connection with the frame, a vertical moving source is mounted on the mounting bracket, and a rotary power source is slidably connected to the mounting bracket.

[0013] By adopting the above technical solution, the mounting bracket and the frame are slidably connected, which enables the lateral power source to drive the mounting bracket and the rotary power source to move laterally, thereby enabling the support component to move laterally. The slidable connection between the rotary power source and the mounting bracket enables the rotary power source to move vertically along the mounting bracket under the action of the vertical moving source.

[0014] In a preferred embodiment, the present application may be further configured such that: the support assembly includes a connecting rod and a support arm, the connecting rod is connected to a rotational power source, the support arm is connected to the rotational power source via the connecting rod, and the support arm is used to form a mobile platform one and a mobile platform two.

[0015] In a preferred embodiment, the application may be further configured such that the support assembly includes a connecting plate, and the support arm is connected to the connecting rod via the connecting plate. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the structure of an embodiment of this application.

[0017] Figure 2 This is a schematic diagram of the organizational structure of the transfer agency in this application.

[0018] Figure 3 This is a schematic diagram of the rotating component structure of this application.

[0019] Reference numerals: 1. Frame; 2. Transfer mechanism; 3. Conveying mechanism one; 31. Drive component; 32. Conveying platform; 4. Conveying mechanism two; 5. Support assembly; 51. Connecting rod; 52. Support arm; 53. Connecting plate; 54. Moving platform one; 55. Moving platform two; 6. Rotation assembly; 61. Rotation power source; 62. Moving power component; 63. Mounting bracket; 64. Lateral movement source; 65. Vertical movement source; 7. Container. Detailed Implementation

[0020] The present application will be further described in detail below with reference to the accompanying drawings.

[0021] Reference Figures 1 to 2 This application discloses a rotary feeding device, which includes a frame 1. The frame 1 is provided with a transfer mechanism 2, a first conveying mechanism 3, and a second conveying mechanism 4. The transfer mechanism 2 is used to transfer the container facility 66. In this embodiment, both the first conveying mechanism 3 and the second conveying mechanism 4 include a driving component and a conveying platform. The driving component can be driven by a motor belt. For ease of description, the driving component and the conveying platform are not shown in the accompanying drawings. The first conveying mechanism 3 is used to receive the fully loaded container facility 66 on the transfer mechanism 2 and drive it to move. The second conveying mechanism 4 is used to transfer the empty container facility 66 to the transfer mechanism 2.

[0022] The transfer mechanism 2 includes a support component 5 and a rotating component 6. The rotating component 6 is used to drive the support component 5 to rotate and move. The support component 5 is used to drive the container facility 66 to move. The rotating component 6 includes a rotational power source 61 and a moving power component 62. The support component 5 and the rotational power source 61 are connected. The rotational power source 61 is used to drive the support component 5 to rotate, and the moving power component 62 is used to drive the rotational power source 61 to move.

[0023] The moving power component 62 includes a mounting bracket 63, a lateral moving source 64, and a vertical moving source 65. The lateral moving source 64 is used to drive the support component 5 to move laterally, and the vertical moving source 65 is used to drive the support component 5 to move vertically. The mounting bracket 63 is slidably connected to the frame 1, and the vertical moving source 65 is mounted on the mounting bracket 63. The rotational power source 61 is slidably connected to the mounting bracket 63. In this embodiment, the rotational power source 61 can be a motor, and the lateral and vertical power sources can be driven by motor belts.

[0024] The support assembly 5 includes a connecting rod 51, a support arm 52, and a connecting plate 53. The support arm 52 is connected to the connecting plate 53, the connecting plate 53 is connected to the connecting rod 51, and the connecting rod 51 is connected to the rotary power source 61. The number of support arms 52 is set to two sets, and the two sets of support arms 52 are arranged opposite each other to form a first mobile platform 54 and a second mobile platform 55. The first mobile platform 54 and the second mobile platform 55 are used to alternately drive the fully loaded container 66 or the unloaded container 66 to move.

[0025] When the support assembly 5 delivers the fully loaded container 66 to the conveying mechanism 3, the vertical power source drives the support assembly 5 downward, and the horizontal power source drives the support assembly 5 backward, causing the moving platform 54 to move to the conveying mechanism 4. The horizontal and vertical power sources work together to position the moving platform 54 below the empty container 66 on the conveying mechanism 4. The vertical power source drives the moving platform 54 upward, placing the container 66 on the moving platform 54. The horizontal power source then moves the moving platform 54 to the container position. At this point, the moving platform 55 faces the fully loaded container. The material container 66, with the cooperation of a horizontal power source and a vertical power source, allows the fully loaded container 66 to be located on the second mobile platform 55. The rotational power source 61 drives the support component 5 to rotate, causing the positions of the first mobile platform 54 and the second mobile platform 55 to be swapped, thereby making the first mobile platform 54 face the container position. The vertical power source moves downward, so that the empty container 66 on the first mobile platform 54 is placed at the container point. The horizontal and vertical power sources cooperate to repeat the above operation, so that the first mobile platform 54 and the second mobile platform 55 continuously transport the empty or fully loaded container 66 to the appropriate position.

[0026] The implementation principle of this embodiment is as follows: the rotary component 6 drives the support component 5 to rotate and move, so that the positions of the first mobile platform 54 and the second mobile platform 55 can be switched alternately. This allows the support component 5 to place the empty container 66 in the container position when the fully loaded container 66 leaves the container position, without waiting for other structures or operators to intervene. This saves time and resources in the feeding process, thereby making the work more efficient.

[0027] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A rotary feeding device, characterized in that: It includes a frame (1), on which a transfer mechanism (2) is provided. The transfer mechanism (2) is used to transfer the container facility (66). The transfer mechanism (2) includes a support component (5) and a rotating component (6). The rotating component (6) is used to drive the support component (5) to rotate and move. The support component (5) is used to drive the container facility (66) to move. The support component (5) includes a first moving platform (54) and a second moving platform (55). The first moving platform (54) and the second moving platform (55) are used to alternately drive the fully loaded container facility (66) or the unloaded container facility (66) to move.

2. The rotary feeding device according to claim 1, characterized in that: It also includes a first conveying mechanism (3) and a second conveying mechanism (4). The first conveying mechanism (3) is used to receive the fully loaded container (66) on the transfer mechanism (2) and move it. The second conveying mechanism (4) is used to transfer the empty container (66) to the transfer mechanism (2).

3. The rotary feeding device according to claim 1, characterized in that: The rotary assembly (6) includes a rotary power source (61) and a moving power component (62). The support assembly (5) is connected to the rotary power source (61). The rotary power source (61) is used to drive the support assembly (5) to rotate, and the moving power component (62) is used to drive the rotary power source (61) to move.

4. A rotary feeding device according to claim 3, characterized in that: The moving power component (62) includes a lateral moving source (64) and a vertical moving source (65). The lateral moving source (64) is used to drive the support component (5) to move laterally, and the vertical moving source (65) is used to drive the support component (5) to move vertically.

5. A rotary feeding device according to claim 4, characterized in that: The moving power unit (62) includes a mounting bracket (63) for sliding connection with the frame (1), a vertical moving source (65) mounted on the mounting bracket (63), and a rotating power source (61) slidably connected to the mounting bracket (63).

6. A rotary feeding device according to claim 3, characterized in that: The support assembly (5) includes a connecting rod (51) and a support arm (52). The connecting rod (51) is connected to a rotary power source (61), and the support arm (52) is connected to the rotary power source (61) through the connecting rod (51). The support arm (52) is used to form a first mobile platform (54) and a second mobile platform (55).

7. A rotary feeding device according to claim 6, characterized in that: The support assembly (5) includes a connecting plate (53), and the support arm (52) is connected to the connecting rod (51) through the connecting plate (53).