A high efficiency cycle frame device

Abstract

The utility model relates to medical equipment field, concretely is a kind of high -efficient cycle frame sending device, including frame separating subassembly, frame sending subassembly, the frame separating subassembly includes motor one, the drive for this device, worm, the worm one end is fixedly connected with motor one output end, for the transmission of force, control component, by worm drive, the movement track of control mechanism. In the utility model, by the setting of frame separating subassembly, can by motor one drive worm rotation, then drive worm wheel rotation, then worm wheel can be controlled two side limit block one and limit block two by stand one and stand two, to drive support claw subassembly and separate claw subassembly to carry out alternate motion, then when separate claw subassembly extends support claw subassembly and retracts, the material frame of bottom can be separated and fall into frame sending subassembly and be transported, material frame can be automatically separated and transported, improve the automation level, and improve the frame sending efficiency of material frame.

Description

Technical Field

[0001] This utility model relates to the field of medical equipment, specifically a high-efficiency circulating frame launching device. Background Technology

[0002] In modern industrial production, especially in the field of medical equipment, material crates are important carriers for carrying and transporting materials. Their recycling efficiency plays a key role in the smoothness and efficiency of the entire production process. Traditional material crate handling methods rely heavily on manual operation, which has problems such as high labor intensity, low efficiency, and high labor costs. In addition, manual operation is prone to errors, resulting in inaccurate placement of material crates and untimely separation, which affects production progress and product quality.

[0003] Although some enterprises have introduced automated crate feeding equipment, the existing equipment often suffers from defects such as complex structure, high failure rate, and high maintenance cost, making it difficult to meet the needs of high-intensity and long-term production. At the same time, most equipment has a single function and cannot achieve full automation and efficient circulation of material crate placement, separation, and transportation. It is difficult to adapt to the diverse production scenarios and the processing needs of material crates of different specifications. It also has shortcomings in production line layout optimization and space utilization, which limits the improvement of enterprise production efficiency and cost control. Therefore, an efficient circulating crate feeding device is proposed to solve the above-mentioned problems. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides a high-efficiency circulating frame feeding device, which solves the problems mentioned in the background art, such as the long time-consuming manual feeding and unloading operations that affect the overall detection efficiency, and the inaccurate weight of manual feeding that affects the detection data.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a high-efficiency circulating frame feeding device, comprising a frame separating assembly and a frame feeding assembly. The frame separating assembly includes a motor for driving the device, a worm gear with one end fixedly connected to the output end of the motor for force transmission, a control assembly driven by the worm gear to control the movement trajectory of the mechanism, a support claw assembly driven by the control assembly for supporting the placement of the material frames, and a separating claw assembly driven by the control assembly to move in an alternating manner with the support claw assembly to separate the material frames. A support plate is provided for supporting the entire mechanism, and the motor, worm gear, control assembly, support claw assembly, and separating claw assembly are all mounted on the top of the support plate.

[0006] Preferably, the control component includes a worm gear, a first limiting block, a first bearing, a first column, a second limiting block, a second bearing, and a second column. The worm meshes with the worm gear. The first column and the second column are fixedly connected to the bottom sides of the rotating worm gear, respectively. The second bearing is fixedly connected to the outer wall of the second column, and the first bearing is fixedly connected to the outer wall of the first column.

[0007] Preferably, the support claw assembly includes a connecting rod, a support claw, a slide rail, and a slider. The outer wall of the slider is slidably connected to the inside of the slide rail. The slider is fixedly connected to the connecting rod. The support claw is fixedly installed on the top of the connecting rod. The bottom of the slide rail is fixedly connected to the top of the support plate. The top of the slider is fixedly connected to the limiting block.

[0008] Preferably, the separator claw assembly includes a second connecting rod, an auxiliary support claw, a second slide rail, a second slider, and a separator claw. The bottom of the second slide rail is fixedly connected to the top of the first support plate. The outer wall of the second slider is slidably connected to the inside of the second slide rail. The top of the second slider is fixedly connected to the bottom of the first limiting block. The second connecting rod is fixedly connected to the second slider. The separator claw is fixedly installed on the outer wall of the second connecting rod, and the auxiliary support claw is fixedly installed on the outer wall of the second connecting rod.

[0009] Preferably, the frame assembly comprises two symmetrical sets, and the frame assemblies on both sides are connected by a transmission belt. The transmission belt is disposed between the worm gears on both sides to achieve synchronous movement of the frame assemblies on both sides.

[0010] Preferably, the feeding frame assembly includes a second motor, a conveyor belt, and a baffle. The conveyor belt is driven by the second motor and pushes the material frame to be conveyed through the baffle.

[0011] Preferably, the baffles are spaced apart on the conveyor belt to promote the orderly conveying of the material frames and prevent the material frames from shifting or piling up during conveying.

[0012] As can be seen from the above technical solutions, the high-efficiency cyclic firing device provided in the embodiments of this specification has at least the following beneficial effects:

[0013] This invention, through the setting of the frame-separating component, allows the worm gear to rotate via a motor, which in turn drives the worm wheel to rotate. The worm wheel can then be controlled by two limit blocks on both sides via columns one and two, thereby causing the support claw component and the separating claw component to move alternately. When the separating claw component extends and the support claw component retracts, the material frame at the bottom can be separated and fall into the feeding frame component for conveying. This allows the material frame to be automatically separated and conveyed, improving the level of automation and the feeding efficiency of the material frame. Attached Figure Description

[0014] The accompanying drawings, which are included to provide a further understanding of the present invention, form part of this application:

[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0016] Figure 2 This is a schematic diagram of the structure of the support plate one in this utility model;

[0017] Figure 3 This is a schematic diagram of the support claw assembly in this utility model;

[0018] Figure 4 This is a schematic diagram of the separator claw assembly in this utility model;

[0019] Figure 5 This is a schematic diagram of the limiting block in this utility model;

[0020] Figure 6 This is a schematic diagram of the structure of the hair frame component in this utility model.

[0021] In the diagram: 1. Frame assembly; 11. Motor 1; 12. Worm gear; 13. Worm wheel; 131. Limiting block 1; 132. Bearing 1; 133. Column 1; 134. Limiting block 2; 135. Bearing 2; 136. Column 2; 14. Support claw assembly; 141. Connecting rod 1; 142. Support claw; 143. Slide rail 1; 144. Slider 1; 15. Separating claw assembly; 151. Connecting rod 2; 152. Auxiliary support claw; 153. Slide rail 2; 154. Slider 2; 155. Separating claw; 16. Support plate 1; 2. Frame assembly; 21. Motor 2; 22. Conveyor belt; 23. Baffle; 3. Transmission belt. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Example

[0024] Please see Figures 1-6As shown, a high-efficiency circulating frame feeding device includes a frame separating assembly 1 and a frame feeding assembly 2. The frame separating assembly 1 includes a motor 11 for driving the device, a worm gear 12, one end of which is fixedly connected to the output end of the motor 11 for force transmission, a control assembly driven by the worm gear 12 to control the movement trajectory of the mechanism, a support claw assembly 14 driven by the control assembly to support the placement of the material frame, a separating claw assembly 15 driven by the control assembly to move in an alternating manner with the support claw assembly 14 to separate the material frame, and a support plate 16 for supporting the entire mechanism. The motor 11, worm gear 12, control assembly, support claw assembly 14, and separating claw assembly 15 are all mounted on the top of the support plate 16.

[0025] Furthermore, in actual use, the efficient circulating frame feeding device, driven by the motor 11, causes the worm 12 to rotate. Simultaneously, the transmission belt 3 connects the two sides, allowing them to move synchronously. The rotation of the worm 12 further drives the rotation of the worm wheel 13. During the rotation of the worm wheel 13, the first column 133 and the second column 136 at the bottom of the worm wheel 13 move alternately and in an orderly manner. Specifically, when the second column 136 moves forward, it pushes the second limiting block 134 through the bearing 135, causing the limiting block 134 to slide the first slider 144 outward. The outward sliding of the first slider 144 causes the support claws 142 on both sides of the connecting rod 141 to extend, thus providing a platform for placing the material frame. At the same time, the first column 133, through the bearing 132, drives the limit block 144... The first block 131 retracts, causing the second slider 154 to retract via the second connecting rod 151, which in turn drives the two separating claws 155 on both sides to retract. As the worm gear 13 continues to rotate, the first column 133 moves forward, causing the first limit block 131 to slide outward via the first bearing 132. The outward sliding of the first limit block 131 pushes the second slider 154 to slide outward, which in turn causes the second slider 154 to drive the second connecting rod 151 to move outward. The separating claws 155 on both sides of the second connecting rod 151 will insert into the gap between the two material frames, thereby separating the material frames. Subsequently, the new material frame will be placed on the auxiliary support claw 152 at the top of the second connecting rod 151. During this process, the worm gear 13 will continue to drive the second column 136 to retract, and the second bearing 135 will control the second limit block 134 to slide inward, which in turn causes the second limit block 134 to drive the first slider 144 to slide inward. The connecting rod 141 connected to slider 144 and its supporting claws 142 on both sides will be retracted, causing the separated bottom material frame to lose the support of the supporting claws 142 and fall onto the bottom conveyor belt 22. The conveyor belt 22 will be driven by motor 21, and the baffles 23 on the conveyor belt 22 will push the material frame to achieve continuous conveying of the material frame.

[0026] In this embodiment, the device successfully achieves efficient receiving, separation, and continuous transportation of material frames by employing an automated circulating transmission mechanism, a synchronous and precise control mechanism, and a stable and efficient conveying mechanism. Specifically, the automated circulating transmission mechanism ensures the continuous operation of the device, the synchronous and precise control mechanism ensures the precise coordination of each operation step, thereby improving the overall work efficiency, and the stable conveying mechanism ensures the safety and reliability of materials during the transmission process. The cooperation between these mechanisms enables the automated operation of the device, thereby improving the efficiency of material frame dispensing.

[0027] In use, the high-efficiency circulating frame feeding device of this utility model involves a motor 11 driving a worm gear 12 to rotate, which, through a transmission belt 3, causes the two sides of the mechanism to move synchronously. The rotation of the worm gear 12 drives the worm wheel 13 to rotate. When the worm wheel 13 rotates, the first column 133 and the second column 136 at the bottom of the worm wheel 13 move alternately. When the second column 136 moves forward, it pushes the second limiting block 134 through the second bearing 135, causing the second limiting block 134 to drive the first slider 144 to slide outward. This causes the support claws 142 on both sides of the connecting rod 141 to extend, placing the material frame on top. The first column 133 then drives the first limiting block 131 to retract through the first bearing 132, causing the second slider 154 to drive the two side separating claws 155 to retract through the connecting rod 151. Under the rotation of the worm wheel 13, the first column 133 moves forward, thereby driving the first column 133 to move forward through the first bearing 132. When the limiting block 131 slides outward, it can push the slider 2 154 outward. The slider 2 154 will then drive the connecting rod 2 151 outward, causing the separating claws 155 on both sides of the connecting rod 2 151 to insert into the gap between the two material frames, thus separating them. The subsequent material frame will be placed on the auxiliary support claw 152 at the top of the connecting rod 2 151. At this time, the worm gear 13 will drive the column 2 136 to retract, thereby controlling the limiting block 2 134 to slide inward through the bearing 2 135. This causes the limiting block 2 134 to drive the slider 1 144 to slide inward. The connecting rod 1 141 connected to the slider 1 144 and the support claws 142 on both sides will be retracted. The separated bottom material frame will lose the support of the support claws 142 and fall onto the bottom conveyor belt 22. The conveyor belt 22 will be driven by the motor 2 21, and the baffle 23 on the conveyor belt 22 will push the material frame to transport it.

[0028] The above embodiments are only used to illustrate the present utility model, and are not intended to limit the present utility model. Those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present utility model. Therefore, all equivalent technical solutions also fall within the scope of the present utility model. The patent protection scope of the present utility model should be defined by the claims.

Claims

1. A high-efficiency circulating frame-dispensing device, characterized in that, The components include a frame-splitting component (1) and a frame-splitting component (2). The frame-splitting component (1) includes: Electric motor 1 (11) is used to drive the device; The worm (12) is fixedly connected at one end to the output end of the motor (11) for force transmission; The control component, driven by the worm gear (12), controls the movement trajectory of the control mechanism; The support claw assembly (14) is driven by the control assembly to support the placement of the material box; The separating claw assembly (15) is driven by the control assembly and moves in an alternating manner with the support claw assembly (14) to achieve the separation of the material box; Support plate 1 (16) is used to support the overall mechanism. The motor 1 (11), worm gear (12), control component, support claw assembly (14) and separator claw assembly (15) are all installed on the top of support plate 1 (16).

2. The high-efficiency circulating frame-generating device according to claim 1, characterized in that: The control assembly includes a worm gear (13), a first limiting block (131), a first bearing (132), a first column (133), a second limiting block (134), a second bearing (135), and a second column (136). The worm (12) meshes with the worm gear (13). The first column (133) and the second column (136) are fixedly connected to the bottom sides of the rotating worm gear (13). The second bearing (135) is fixedly connected to the outer wall of the second column (136), and the first bearing (132) is fixedly connected to the outer wall of the first column (133).

3. The high-efficiency circulating frame feeding device according to claim 1, characterized in that: The support claw assembly (14) includes a connecting rod (141), a support claw (142), a slide rail (143), and a slider (144). The outer wall of the slider (144) is slidably connected to the inside of the slide rail (143). The slider (144) is fixedly connected to the connecting rod (141). The support claw (142) is fixedly installed on the top of the connecting rod (141). The bottom of the slide rail (143) is fixedly connected to the top of the support plate (16). The top of the slider (144) is fixedly connected to the limiting block (134).

4. The high-efficiency circulating frame feeding device according to claim 1, characterized in that: The separator claw assembly (15) includes a second connecting rod (151), an auxiliary support claw (152), a second slide rail (153), a second slider (154), and a separator claw (155). The bottom of the second slide rail (153) is fixedly connected to the top of the first support plate (16). The outer wall of the second slider (154) is slidably connected to the inside of the second slide rail (153). The top of the second slider (154) is fixedly connected to the bottom of the first limiting block (131). The second connecting rod (151) is fixedly connected to the second slider (154). The separator claw (155) is fixedly installed on the outer wall of the second connecting rod (151). The auxiliary support claw (152) is fixedly installed on the outer wall of the second connecting rod (151).

5. The high-efficiency circulating frame-generating device according to claim 1, characterized in that: The frame assembly (1) includes two symmetrical sets on the left and right. The frame assemblies (1) on both sides are connected by a transmission belt (3). The transmission belt (3) is set between the worm gears (12) on both sides to realize the synchronous movement of the frame assemblies (1) on both sides.

6. The high-efficiency circulating frame feeding device according to claim 1, characterized in that: The feeding frame assembly (2) includes a second motor (21), a conveyor belt (22), and a baffle (23). The conveyor belt (22) is driven by the second motor (21) and pushes the material frame to be conveyed through the baffle (23).

7. The high-efficiency circulating frame feeding device according to claim 6, characterized in that: The baffles (23) are spaced on the conveyor belt (22) to push the material frames to be transported in an orderly manner and to prevent the material frames from shifting or piling up during transport.

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