An automatic pusher packaging device

Abstract

The utility model belongs to the technical field of medical supplies, concretely relates to an automatic push packaging device, including base, the top of base is provided with the article platform, is provided with a plurality of equidistance's placement groove on the article platform, is provided with the drive mechanism for pushing medical injection molding spare on the article platform, each placement groove inside all is provided with the packing bag for packing medical injection molding spare, the bottom of packing bag is provided with the adjusting mechanism for adjusting medical injection molding spare stacking height, through drive mechanism, medical injection molding spare on the article platform is automatically pushed to packing bag, through adjusting mechanism, the height of medical injection molding spare that stacks in packing bag is automatically adjusted, has improved packing efficiency and packing quality.

Description

Technical Field

[0001] This utility model belongs to the field of medical product testing technology, specifically relating to an automatic push packaging device. Background Technology

[0002] In the field of medical pathology testing, medical injection molded parts are key consumables in the process of tissue sample processing. Traditional manual or semi-automatic methods for handling medical injection molded parts suffer from low efficiency and error-proneness, failing to meet the demands of modern medical testing for high-throughput and high-precision sample processing. With the development of medical technology, the volume of pathology test samples has increased significantly, placing higher demands on the rapid and accurate processing of medical injection molded parts. Therefore, the development of devices capable of automating the pushing and packaging of medical injection molded parts has become an urgent need in the industry. Utility Model Content

[0003] To address the shortcomings of existing technologies, this utility model provides an automatic pushing packaging device. The device automatically pushes medical injection molded parts from a placement platform into a packaging bag via a drive mechanism. The height of the stacked medical injection molded parts inside the packaging bag is automatically adjusted by an adjustment mechanism, thereby improving packaging efficiency and quality. This solves the problems of low efficiency and error-proneness in traditional manual or semi-automatic medical injection molded part processing methods, which cannot meet the needs of modern medical testing for high-throughput and high-precision sample processing.

[0004] To achieve the above objectives, this utility model is implemented through the following technical solution: an automatic pushing packaging device, including a base, a placing platform provided on the top of the base, a plurality of equidistant placement slots provided on the placing platform, a driving mechanism for pushing medical injection molded parts provided on the placing platform, a packaging bag for packaging medical injection molded parts being provided inside each placement slot, and an adjustment mechanism for adjusting the stacking height of medical injection molded parts being provided at the bottom of the packaging bag.

[0005] Preferably, the adjustment mechanism includes a first cylinder disposed at the bottom of the placement slot, the output end of the first cylinder being connected to a receiving plate, and the receiving plate contacting the bottom of the first medical injection molded part to be packaged.

[0006] Preferably, the placement groove includes a first groove disposed on the top of the base, and a second groove disposed on one side of the first groove, the second groove being disposed on one side of the first groove in a sloping shape.

[0007] Preferably, a blocking block is provided inside the second groove, and an opening is provided in the center of the blocking block for the receiving plate to pass through.

[0008] Preferably, the depth of the first groove is slightly greater than the thickness of the medical injection molded part, and the depth of the second groove is slightly greater than the width of the medical injection molded part.

[0009] Preferably, the surface area of ​​the receiving plate is slightly smaller than that of the medical injection molded part, and the surface area of ​​the blocking block is the same as that of the medical injection molded part.

[0010] Preferably, the drive mechanism includes a drive motor disposed on the top of the base, and the output end of the drive motor is connected to a fixed push plate.

[0011] Preferably, the bottom of the fixed push plate is provided with clearance grooves that match the sides of the placement groove.

[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: the medical injection molded parts on the placement platform are automatically pushed to the packaging bag by the drive mechanism, and the height of the medical injection molded parts stacked in the packaging bag is automatically adjusted by the adjustment mechanism, thereby improving packaging efficiency and packaging quality.

[0013] Additional aspects and advantages of this utility model application will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of this utility model application. Attached Figure Description

[0014] Figure 1 A three-dimensional structural diagram of an automatic packaging pusher. Figure 1 .

[0015] Figure 2 A three-dimensional structural diagram of an automatic packaging pusher. Figure 2 .

[0016] Figure 3 This is a three-dimensional front view of an automatic packaging pusher device.

[0017] Figure 4 This is an exploded three-dimensional view of an automatic push packaging device.

[0018] Figure 5 This is a three-dimensional structural diagram of the adjustment mechanism of an automatic packaging device.

[0019] In the diagram: 1. Base; 2. Storage platform; 3. Placement slot; 31. First groove; 32. Second groove; 321. Blocking block; 322. Opening; 4. Drive mechanism; 41. Drive motor; 42. Fixed push plate; 421. Clearance groove; 5. Adjustment mechanism; 51. First cylinder; 52. Receiving plate; 6. Medical injection molded part. Detailed Implementation

[0020] The embodiments of this utility model application will be described in detail below with reference to the accompanying drawings and examples. The following examples are used to illustrate this utility model application, but should not be used to limit the scope of this utility model application. All other embodiments obtained by those skilled in the art without inventive effort are within the scope of protection of this utility model application.

[0021] Combination Figure 1 , Figure 2 , Figure 3 and Figure 5 As shown, an automatic push packaging device includes a base 1, a placement platform 2 is provided on the top of the base 1, a plurality of equidistant placement slots 3 are provided on the placement platform 2, a drive mechanism 4 for pushing medical injection molded parts 6 is provided on the placement platform 2, a packaging bag for packaging medical injection molded parts 6 is provided inside each placement slot 3, and an adjustment mechanism 5 for adjusting the stacking height of medical injection molded parts 6 is provided at the bottom of the packaging bag.

[0022] This utility model proposes an automatic push packaging device. The base 1 serves as the fundamental support component of the entire automatic push packaging device, providing a platform for the installation and fixation of other components. The placement platform 2 is located on top of the base 1 and is the main area for placing medical injection molded parts 6 and performing related operations. Several placement slots 3 are provided on the placement platform 2, equidistantly distributed, for placing the medical injection molded parts 6 and providing independent storage space for each part.

[0023] The drive mechanism 4 is mounted on the storage platform 2. Its main function is to push the medical injection molded part 6, allowing it to move on the storage platform 2 and achieve an automatic pushing function. The adjustment mechanism 5 is located inside each placement slot 3 and is used to adjust the stacking height of the medical injection molded part 6 within the packaging bag, ensuring that the medical injection molded part 6 achieves a suitable stacking state within the packaging bag. The packaging bag is placed inside each placement slot 3 to package the medical injection molded part 6, wrapping it up and providing protection and storage. The packaging bag contains the medical injection molded part 6.

[0024] In each placement slot 3, a certain number of medical injection molded parts 6 are pre-placed in the packaging bag as needed. At this time, the adjusting mechanism 5 is in its initial position to accommodate the initial stacking height of the medical injection molded parts 6. When further processing of the medical injection molded parts 6 is required, the drive mechanism 4 starts to work. The drive mechanism 4 generates thrust, which acts on the medical injection molded parts 6, pushing the medical injection molded parts 6 to move on the placement platform 2, pushing the medical injection molded parts 6 to the designated position or performing subsequent operations.

[0025] As the medical injection molded parts 6 are continuously placed into the packaging bag within the placement slot 3, the stacking height of the medical injection molded parts 6 within the packaging bag gradually increases. At this point, the adjustment mechanism 5 begins to function, automatically adjusting its own state according to the changes in the stacking height of the medical injection molded parts 6 (for example, the adjustment mechanism 5 may be composed of retractable parts that gradually retract as the stacking height increases, providing sufficient placement space for new medical injection molded parts 6), ensuring that the medical injection molded parts 6 maintain a suitable stacking height within the packaging bag, avoiding damage to the packaging bag or the medical injection molded parts 6 due to excessive stacking, and ensuring the smooth progress of the packaging process.

[0026] The entire automated push packaging device achieves automatic pushing of medical injection molded parts 6 and automatic adjustment of stacking height within the packaging bag through the coordinated work of its various components, thereby improving packaging efficiency and packaging quality.

[0027] Combination Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, the adjustment mechanism 5 includes a first cylinder 51 disposed at the bottom of the placement slot 3. The output end of the first cylinder 51 is connected to a receiving plate 52, and the receiving plate 52 contacts the bottom of the first medical injection molded part 6 to be packaged.

[0028] Specifically, the first cylinder 51, serving as the power source for the adjustment mechanism 5, is located at the bottom of the placement slot 3. The receiving plate 52 is connected to the output end of the first cylinder 51. The receiving plate 52 is a flat plate structure with a certain area and strength, which directly contacts the bottom of the first medical injection molded part 6 to be packaged, providing support for the medical injection molded part 6.

[0029] Before packaging the medical injection molded part 6 begins, the first cylinder 51 is in its initial state. At this time, the receiving plate 52 is located at a relatively high position at the bottom of the placement slot 3 (this height is preset according to the placement requirements of the first medical injection molded part 6), waiting to receive the first medical injection molded part 6. When the first medical injection molded part 6 is placed into the packaging bag in the placement slot 3, the bottom of the medical injection molded part 6 will fall directly onto the receiving plate 52. The receiving plate 52 bears the weight of the medical injection molded part 6, providing stable support for the medical injection molded part 6.

[0030] As subsequent medical injection molded parts 6 are continuously placed into the packaging bag, the stacking height of the medical injection molded parts 6 within the packaging bag gradually increases. To adapt to changes in stacking height and prevent the packaging bag from breaking or the medical injection molded parts 6 from being stacked too high, the first cylinder 51 begins to operate. The output end of the first cylinder 51 drives the receiving plate 52 to move slowly downwards, gradually increasing the distance between the receiving plate 52 and the bottom of the placement slot 3. This provides sufficient stacking space for the subsequently placed medical injection molded parts 6, thereby achieving automatic adjustment of the stacking height of the medical injection molded parts 6 within the packaging bag. Throughout the packaging process, the first cylinder 51 continuously adjusts the position of the receiving plate 52 according to the stacking status of the medical injection molded parts 6, ensuring the smooth progress of the packaging process.

[0031] Combination Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, the placement groove 3 includes a first groove 31 disposed on the top of the base 1, and a second groove 32 disposed on one side of the first groove 31. The second groove 32 is disposed on one side of the first groove 31 in a sloping shape.

[0032] Specifically, the first groove 31 is located at the top of the base 1, and the second groove 32 is located on one side of the first groove 31 and is sloped. The sloped design creates a certain slope connection between the second groove 32 and the first groove 31, providing the main receiving space for the medical injection molded parts 6 and packaging bags, etc. The medical injection molded parts 6 and packaging bags are mainly placed in the second groove 32 for packaging and other operations.

[0033] Combination Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, a blocking block 321 is provided inside the second groove 32, and an opening 322 for the receiving plate 52 to pass through is provided in the center of the blocking block 321.

[0034] Specifically, the blocking block 321 is located inside the second groove 32 and is used to block or limit the movement height of certain stacked medical injection molded parts 6, serving as a positioning and limiting function. The opening 322 is opened at the center of the blocking block 321. The size and shape of the opening 322 are adapted to the receiving plate 52, allowing the receiving plate 52 to pass through, thereby ensuring that the receiving plate 52 can smoothly pass through the blocking block 321 during movement and realize its normal function in the placement groove 3.

[0035] Before the medical injection molded part 6 is packaged and related operations are performed, the receiving plate 52 is in its initial position. At this time, the blocking block 321 is located inside the second groove 32, and its opening 322 corresponds to the moving path of the receiving plate 52, but the receiving plate 52 has not yet passed through the opening 322. The blocking block 321 serves to stabilize the structure of the second groove 32 and provide a positioning reference for subsequent operations.

[0036] When packaging the medical injection molded parts 6 begins, and as the medical injection molded parts 6 are continuously stacked inside the packaging bag, the receiving plate 52 needs to be adjusted downwards according to the stacking height. During the descent of the receiving plate 52, it gradually approaches the blocking block 321. Because the size of the opening 322 in the center of the blocking block 321 is compatible with the size of the receiving plate 52, the receiving plate 52 can smoothly pass through the opening 322 and continue to move downwards to accommodate the increasing stacking height of the medical injection molded parts 6, providing sufficient stacking space for subsequent medical injection molded parts 6.

[0037] In addition to allowing the receiving plate 52 to pass through, the blocking block 321 also serves to block and limit other objects that may enter the second groove 32. The blocking block 321 can, to a certain extent, limit the movement direction of the medical injection molded part 6 during the pushing process, causing it to move along a predetermined path.

[0038] Combination Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, the depth of the first groove 31 is slightly greater than the thickness of the medical injection molded part 6, and the depth of the second groove 32 is slightly greater than the width of the medical injection molded part 6.

[0039] Specifically, since the depth of the first groove 31 is slightly greater than the thickness of the medical injection molded part 6, when the medical injection molded part 6 is placed in the first groove 31, it can be stably placed within the first groove 31. This prevents the medical injection molded part 6 from shaking or shifting significantly within the placement groove 3, ensuring that the medical injection molded part 6 remains in a relatively fixed position during subsequent packaging operations (such as stacking, sealing, etc.), thus improving the accuracy and stability of the packaging.

[0040] The depth design, slightly exceeding the thickness of the medical injection molded part 6, also facilitates operation by staff or automated equipment within the first groove 31. Sufficient space is also available for subsequent inspections and adjustments of the medical injection molded part 6, without being restricted by a shallow groove.

[0041] The second groove 32 is sloping and its depth is slightly greater than the width of the medical injection molded part 6. It provides good guidance when the medical injection molded part 6 needs to be pushed out of the placement groove 3. During the pushing process, the medical injection molded part 6 can smoothly slide out along the slope of the second groove 32. The depth of the second groove 32, slightly greater than the width of the medical injection molded part 6, ensures that the medical injection molded part 6 will not get stuck or deviate from the predetermined path due to insufficient depth of the second groove 32, making the pushing operation smoother and more accurate.

[0042] As the medical injection molded part 6 moves along the second groove 32, the depth, slightly greater than the width of the medical injection molded part 6, provides lateral support to prevent it from tipping over. When the medical injection molded part 6 is subjected to a pushing force, the sidewall of the second groove 32 restricts its lateral movement, ensuring it slides stably along the ramp, thus improving the reliability and safety of the entire pushing process.

[0043] Combination Figure 1 , Figure 2 , Figure 3 and Figure 4 As shown, the surface area of ​​the receiving plate 52 is slightly smaller than that of the medical injection molded part 6, and the surface area of ​​the blocking block 321 is the same as that of the medical injection molded part 6.

[0044] Specifically, the receiving plate 52 is connected to the output end of the first cylinder 51 and is used to directly support the medical injection molded part 6 to be packaged. Its surface area is slightly smaller than the surface area of ​​the medical injection molded part 6, meaning that the receiving plate 52 cannot completely cover the bottom of the medical injection molded part 6.

[0045] The blocking block 321 is disposed inside the second groove 32, with an opening 322 in the center for the receiving plate 52 to pass through. The surface area of ​​the blocking block 321 is the same as that of the medical injection molded part 6, that is, the size and shape of the blocking block 321 are similar to those of the medical injection molded part 6, and it can play a corresponding role in the medical injection molded part 6 to a certain extent.

[0046] Combination Figure 1 , Figure 2 , Figure 3 and Figure 5 As shown, the drive mechanism 4 includes a drive motor 41 mounted on the top of the base 1, and the output end of the drive motor 41 is connected to a fixed push plate 42.

[0047] Specifically, the drive motor 41, serving as the power source for the drive mechanism 4, is located on top of the base 1. The drive motor 41 is a device that converts electrical energy into mechanical energy, generating rotational torque through internal electromagnetic induction to drive the connected components. The performance parameters of the drive motor 41 (such as power and speed) are selected based on actual packaging requirements to ensure sufficient power to propel the medical injection molded part 6.

[0048] The fixed push plate 42 is connected to the output end of the drive motor 41. The fixed push plate 42 is a flat plate structure with a certain area and strength, usually made of metal or other sturdy and durable materials to ensure that it will not deform or be damaged during the pushing of the medical injection molded part 6. The surface shape and size of the fixed push plate 42 are designed according to the shape and packaging requirements of the medical injection molded part 6 to ensure that it can effectively contact the medical injection molded part 6 and apply pushing force.

[0049] When the medical injection molded part 6 is not being pushed, the drive motor 41 is stationary, and the fixed push plate 42 is also in its initial position, not in contact with the medical injection molded part 6. At this time, the medical injection molded part 6 is placed in the appropriate position in the placement slot 3, waiting for subsequent pushing and packaging operations.

[0050] When it is necessary to push the medical injection molded part 6 out of the placement slot 3 or perform other pushing operations, the control system sends a start signal to the drive motor 41. Upon receiving the signal, the drive motor 41 begins to operate, and its internal rotor begins to rotate under the action of electromagnetic force, converting electrical energy into mechanical energy. The output end of the drive motor 41 is connected to the fixed push plate 42. As the drive motor 41 rotates, the output end drives the fixed push plate 42 to move in a predetermined direction. During the movement, the fixed push plate 42 gradually approaches and contacts the medical injection molded part 6.

[0051] When the fixed push plate 42 contacts the medical injection molded part 6, it applies a pushing force to the part, causing it to move in the pushing direction. During this process, the drive motor 41 continuously provides power to ensure that the fixed push plate 42 can push the medical injection molded part 6 at a stable speed and force until it reaches the designated position or the pushing operation is completed.

[0052] Once the medical injection molded part 6 reaches the predetermined position or completes the pushing operation, the control system sends a stop signal to the drive motor 41. Upon receiving the signal, the drive motor 41 stops rotating, and the fixed push plate 42 also stops moving, awaiting the next pushing operation.

[0053] Combination Figure 1 , Figure 2 , Figure 3 and Figure 5 As shown, the bottom of the fixed push plate 42 is provided with clearance grooves 421 that match the two sides of the placement groove 3.

[0054] Specifically, the clearance groove 421 is located at the bottom of the fixed push plate 42, and its shape and size match the structures on both sides of the placement groove 3. The function of the clearance groove 421 is to avoid the structures on both sides of the placement groove 3 during the movement of the fixed push plate 42, thus preventing interference.

[0055] The above embodiments only illustrate one or more implementation methods of this utility model application, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of this utility model application. It should be noted that those skilled in the art can make several modifications and improvements without departing from the concept of this utility model application, and these all fall within the protection scope of this utility model application. Therefore, the protection scope of this utility model application should be determined by the appended claims.

Claims

1. An automatic push packaging device comprising a base (1), the top of which is provided with a placement platform (2), characterized in that, The storage platform (2) is provided with several equally spaced placement slots (3). The storage platform (2) is provided with a drive mechanism (4) for pushing medical injection molded parts (6). Each placement slot (3) is provided with a packaging bag for packaging medical injection molded parts (6). The bottom of the packaging bag is provided with an adjustment mechanism (5) for adjusting the stacking height of medical injection molded parts (6).

2. An automatic pusher packaging device according to claim 1, characterized in that The adjustment mechanism (5) includes a first cylinder (51) located at the bottom of the placement slot (3), and the output end of the first cylinder (51) is connected to a receiving plate (52), which contacts the bottom of the first medical injection molded part (6) to be packaged.

3. An automatic pusher packaging device according to claim 2, characterized in that The placement groove (3) includes a first groove (31) provided on the top of the base (1), and a second groove (32) provided on one side of the first groove (31). The second groove (32) is provided on one side of the first groove (31) in a sloping shape.

4. An automatic pusher packaging device according to claim 3, characterized in that The second groove (32) is provided with a blocking block (321) inside, and the center of the blocking block (321) has an opening (322) for the receiving plate (52) to pass through.

5. An automatic packaging device according to claim 3 or 4, characterized in that, The depth of the first groove (31) is slightly greater than the thickness of the medical injection molded part (6), and the depth of the second groove (32) is slightly greater than the width of the medical injection molded part (6).

6. An automatic push-pack apparatus according to claim 5, wherein, The surface area of ​​the receiving plate (52) is slightly smaller than that of the medical injection molded part (6), and the surface area of ​​the blocking block (321) is the same as that of the medical injection molded part (6).

7. An automatic pusher packaging device according to claim 6, characterized in that The drive mechanism (4) includes a drive motor (41) located on the top of the base (1), and the output end of the drive motor (41) is connected to a fixed push plate (42).

8. An automatic pusher packaging device according to claim 7, characterized in that The bottom of the fixed push plate (42) is provided with clearance grooves (421) that match the two sides of the placement groove (3).

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