High-speed slitting and conveying transfer table, high-speed slitting and conveying device and reagent strip production equipment
By using limiting components to press and release the reagent strips during the reagent strip production process, the bottleneck of production efficiency and the problem of strip falling off have been solved, enabling rapid batch transfer and efficient production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUIZHOUCITY BESTAM PRECISION MASCH CO LTD
- Filing Date
- 2025-06-23
- Publication Date
- 2026-07-03
AI Technical Summary
In the existing technology, there are bottlenecks in the production efficiency of reagent strips and problems with reagent strips easily falling off when they are exchanged and moved on the buffer platform.
The high-speed strip conveying and transfer table includes a frame, first and second buffer platforms, and a limiting assembly. The limiting assembly consists of a clamping element and a driver, which is used to clamp and release the reagent strips as the buffer platforms move alternately to ensure their fixation and transfer.
This improved the production efficiency of reagent strips, prevented reagent strips from falling off during exchange and movement on the buffer platform, and enabled rapid batch transfer.
Smart Images

Figure CN224448319U_ABST
Abstract
Description
Technical Field
[0001] This disclosure relates to the field of reagent strip delivery technology, and in particular to a high-speed strip cutting and conveying platform, a high-speed strip cutting and conveying device, and reagent strip production equipment. Background Technology
[0002] In the automated production of reagent strips, the reagent plate is first cut into strips by a cutting component to obtain reagent strips. Then, the reagent strips are adsorbed onto a bag sealing machine by an adsorption device. Next, the reagent strips are loaded into a packaging container by a pushing device. Finally, the bag sealing machine seals the container, thus completing the production of the reagent strips.
[0003] To improve production efficiency, a buffer platform is usually added between the cutting component and the bag sealing machine, such as the buffer storage device disclosed in Chinese Patent Document No. CN116986294A. This can provide better buffering for the reagent strips, thereby effectively improving production efficiency.
[0004] However, the single buffer storage device mentioned in the above literature is difficult to provide sufficient buffer support when the cutting components are operating continuously, resulting in production efficiency bottlenecks and production interruption problems, and still cannot break through to higher production efficiency.
[0005] To address these challenges, some scholars have attempted to introduce a dual-station buffer platform similar to that described in Chinese patent document CN113070583B to effectively solve the aforementioned technical difficulties. In traditional reagent strip production, a certain gap is typically left between the reagent strips in the placement slot of the buffer platform, allowing the adsorption device to adsorb the strips more quickly. However, when using the aforementioned dual-station buffer platform for exchange and movement, the lightweight reagent strips and the presence of gaps make them prone to detachment. Utility Model Content
[0006] The purpose of this disclosure is to overcome the shortcomings of the prior art and provide a high-speed strip cutting and conveying platform, a high-speed strip cutting and conveying device, and a reagent strip production equipment that improves the production efficiency of reagent strips and effectively avoids the problem of reagent strips falling off when they are exchanged and moved on a traditional dual-station buffer platform.
[0007] The purpose of this disclosure is achieved through the following technical solution:
[0008] A high-speed strip-cutting and conveying platform includes a frame, a first buffer platform, and a second buffer platform. The frame forms an interconnected working area and a buffer zone. The first and second buffer platforms are alternately and movably disposed between the working area and the buffer zone. Each of the first and second buffer platforms has multiple placement slots for placing reagent strips.
[0009] The high-speed strip-cutting conveyor also includes a limiting component, which includes a clamping member and a first driver. The clamping member is rotatably disposed on one side of the first buffer platform and / or the second buffer platform. The first driver is disposed on the first buffer platform and / or the second buffer platform. The driving end of the first driver is connected to the clamping member. The first driver is used to drive the clamping member to clamp the reagent strip when the first buffer platform and the second buffer platform move alternately. The first driver is also used to drive the clamping member located in the working area to release the reagent strip.
[0010] In one embodiment, the first buffer platform moves horizontally back and forth along the frame, and the limiting component is disposed on one side of the second buffer platform, which moves horizontally and vertically back and forth along the frame.
[0011] In one embodiment, the clamping member includes a connector, a pressing part, a first rotating part, and a second rotating part. The pressing part is disposed at a first end of the connector, the first rotating part is disposed at a second end of the connector on a first side facing the second buffer platform, and the second rotating part is disposed at a second end of the connector on a second side away from the second buffer platform. The second rotating part is connected to the driving end of the first driver, such that when the first driver drives the second rotating part to a first preset position, the pressing part clamps and fixes the reagent strip; when the first driver drives the second rotating part to a second preset position, the second pressing part releases the reagent strip.
[0012] In one embodiment, the pressing part, the connector, and the first rotating part are connected together to form a mounting cavity, which is used to accommodate the second buffer platform; the side of the pressing part facing the connector has a receiving cavity, which is in communication with the mounting cavity, and the receiving cavity is used to accommodate the reagent strip.
[0013] In one embodiment, the second rotating part includes a first rotating shaft and a pin. A mounting groove is formed in the middle of the second end of the connector away from the second side of the second buffer platform. The first end of the pin is rotatably disposed in the mounting groove through the first rotating shaft. The second end of the pin is connected to the driving end of the first driver.
[0014] In one embodiment, the first rotating part further includes a second rotating shaft, and the second buffer platform has a fastening groove formed on one side corresponding to the first rotating part. The first rotating part is rotatably disposed in the fastening groove by means of the second rotating shaft.
[0015] In one embodiment, the number of the first rotating parts is at least two; and / or,
[0016] The second buffer platform has a clearance groove on one side corresponding to the second rotating part; and / or, the pressing part has a plurality of pressing teeth on the side facing the second buffer platform, each pressing tooth is spaced apart, and each pressing tooth is corresponding to each placement groove, and each pressing tooth is used to press the corresponding reagent strip.
[0017] In one embodiment, the second buffer platform reciprocates horizontally along the frame, and the limiting component is disposed on one side of the first buffer platform, which then reciprocates both horizontally and vertically along the frame; or,
[0018] The number of limiting components is two, namely a first limiting component and a second limiting component. The first limiting component is disposed on one side of the first buffer platform; the second limiting component is disposed on one side of the second buffer platform.
[0019] A high-speed strip-cutting conveying device includes the high-speed strip-cutting conveying transfer table described in any of the above embodiments.
[0020] A reagent strip production device includes the high-speed strip cutting and conveying transfer table described in any of the above embodiments.
[0021] Compared with the prior art, this disclosure has at least the following advantages:
[0022] Since the limiting component includes a clamping member and a first driver, the clamping member is rotatably disposed on one side of the first buffer platform and / or the second buffer platform, and the first driver is disposed on the first buffer platform and / or the second buffer platform, with the driving end of the first driver connected to the clamping member, the first driver is used to drive the clamping member to clamp the reagent strip when the first buffer platform and the second buffer platform move alternately, so that the added limiting component can achieve better fixation of the alternately moving reagent strip. In addition, the first driver is also used to drive the clamping member located in the working area to release the reagent strip so that the adsorption device can adsorb it, thereby completing the batch rapid transfer operation, which not only improves the production efficiency of the reagent strip, but also effectively avoids the problem that the reagent strip is prone to falling off when the traditional dual-station buffer platform is exchanged and moved. Attached Figure Description
[0023] To more clearly illustrate the technical solutions of the embodiments of this disclosure, the accompanying drawings used in the embodiments will be briefly described below. It should be understood that the following drawings only show some embodiments of this disclosure and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.
[0024] Figure 1 This is a schematic diagram of the structure of a high-speed strip-cutting conveyor and transfer table according to an embodiment of the present invention, taken in one direction.
[0025] Figure 2 This is a schematic diagram of the high-speed strip-cutting conveyor and transfer table according to an embodiment of the present invention from another direction;
[0026] Figure 3 for Figure 2 The enlarged view shown at point A in the middle;
[0027] Figure 4 This is a schematic diagram of the structure of the second buffer platform in one direction according to an embodiment of the present invention;
[0028] Figure 5 This is a schematic diagram of the structure of a limiting member in one direction according to an embodiment of the present utility model;
[0029] Figure 6 middle Figure 5 The enlarged view shown at point B in the middle;
[0030] Figure 7 This is a schematic diagram of the high-speed strip-cutting conveying device according to another embodiment of the present invention, taken from one direction.
[0031] Figure 8 for Figure 7 A magnified view of the area shown at point E in the middle.
[0032] Reference numerals: 1. High-speed strip-cutting conveyor; 10. High-speed strip-cutting conveyor transfer table; 100. Frame; 110. Working area; 120. Buffer zone; 200. First buffer platform; 300. Second buffer platform; 310. Placement slot; 500. Limiting component; 510. Clamping component; 511. Connecting component; 5111. Mounting slot; 512. Pressing part; 5121. Receiving cavity; 5122. Pressing tooth; 513. First rotating part; 5131. Second rotating shaft; 514. Second rotating part; 5142. Pin; 5143. Rotating slot; 515. Mounting cavity; 520. First driver; 600. Reagent strip; 710. Third driver; 720. Fourth driver; 20. Cutting assembly; 30. Clamping, correction, and conveying assembly; 40. Adsorption device. Detailed Implementation
[0033] To facilitate understanding of this disclosure, a more complete description will be given below with reference to the accompanying drawings, which illustrate preferred embodiments of the present disclosure. However, this disclosure can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of the disclosure.
[0034] It should be noted that when an element is referred to as being "fixed to" another element, it can be directly attached to the other element or there may be an intervening element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or there may be an intervening element. The terms "vertical," "horizontal," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementation.
[0035] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of this disclosure. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.
[0036] To better understand the technical solutions and beneficial effects of this disclosure, the following detailed description is provided in conjunction with specific embodiments:
[0037] Please refer to 1 to Figure 3 A high-speed strip-cutting conveyor 10 according to one embodiment includes a frame 100, a first buffer platform 200, and a second buffer platform 300. The frame 100 forms a working area 110 and a buffer zone 120 that are interconnected. The first buffer platform 200 or the second buffer platform 300 located in the working area 110 is a feeding area, which is convenient for adsorption by the adsorption device 40. The first buffer platform 200 or the second buffer platform 300 located in the buffer zone 120 is a buffer zone to temporarily store the reagent strips 600 of the cutting assembly 20. The first buffer platform 200 and the second buffer platform 300 are alternately and movably arranged between the working area 110 and the buffer zone 120, so that the first buffer platform 200 and the second buffer platform 300 can be alternately replaced between the working area 110 and the buffer zone 120 of the frame 100. The first buffer platform 200 and the second buffer platform 300 respectively form a plurality of placement slots 310, which are used to place the reagent strips 600 to realize the batch storage of the reagent strips 600.
[0038] It is understood that, since the high-speed strip-cutting conveyor 10 also includes a limiting component 500, please refer to section 4 and... Figure 5The limiting component 500 includes a clamping member 510 and a first driver 520. The clamping member 510 is rotatably disposed on one side of the first buffer platform 200 and / or the second buffer platform 300. The first driver 520 is disposed on the first buffer platform 200 and / or the second buffer platform 300, and the driving end of the first driver 520 is connected to the clamping member 510. The first driver 520 is used to drive the clamping member 510 to clamp the reagent strip 600 when the first buffer platform 200 and the second buffer platform 300 move alternately. The first actuator 520 is also used to drive the clamping member 510 located in the working area 110 to release the reagent strip 600, so that the added limiting component 500 can better fix the alternating reagent strip 600; and the first actuator 520 is also used to drive the clamping member 510 located in the working area 110 to release the reagent strip 600; so that the adsorption device 40 can adsorb, thereby completing the batch rapid transfer operation, which not only improves the production efficiency of the reagent strip 600, but also effectively avoids the problem that the reagent strip 600 is prone to falling off when the traditional dual-station buffer platform is exchanged and moved.
[0039] It is understandable that the multiple placement slots 310 provided on the first buffer platform 200 and the second buffer platform 300 can achieve better positioning of the reagent strip 600, making it less likely for the reagent strip 600 to fall off during horizontal movement, but more likely to shift during vertical movement. Therefore, please refer to... Figure 1 In some embodiments, the first buffer platform 200 moves horizontally (in the G direction) along the frame 100, while the limiting component 500 is disposed on one side of the second buffer platform 300. The second buffer platform 300 moves horizontally (in the G direction) and vertically (in the F direction) along the frame 100, so that the added limiting component 500 can better limit and fix the reagent strip 600 placed on the second buffer platform 300 when it moves vertically.
[0040] Specifically, such as Figure 3 and Figure 5As shown, in one embodiment, the clamping member 510 includes a connector 511, a pressing part 512, a first rotating part 513, and a second rotating part 514. The pressing part 512 is disposed at the first end of the connector 511. The first rotating part 513 is disposed on the first side of the second end of the connector 511 facing the second buffer platform 300. The second rotating part 514 is disposed on the second side of the second end of the connector 511 away from the second buffer platform 300. The second rotating part 514 is connected to the driving end of the first driver 520, so that when the first driver 520 drives the second rotating part 514 to a first preset position, the pressing part 512 clamps and fixes the reagent strip 600; when the first driver 520 drives the second rotating part 514 to a second preset position, the second pressing part 512 releases the reagent strip 600, thereby realizing the clamping and fixing of the reagent strip 600 by the clamping member 510.
[0041] In one embodiment, the first end of the connector 511 is disposed opposite to the second end of the connector 511 to ensure that the pressing part 512, the connector 511 and the first rotating part 513 can be connected to form the mounting cavity 515 so that the mounting cavity 515 can accommodate the second buffer platform 300, thereby ensuring the compactness of the connection between the pressing part 510 and the second buffer platform 300 and the stability of operation.
[0042] like Figure 6 As shown, in one embodiment, the pressing part 512 has a receiving cavity 5121 on the side facing the connector 511. The receiving cavity 5121 is used to receive the reagent strip 600, and the receiving cavity 5121 is in communication with the mounting cavity 515 to ensure that the pressing part 512 can press and fix the reagent strip 600 well.
[0043] like Figure 4 and Figure 6As shown, in one embodiment, the second rotating part 514 includes a first rotating shaft and a pin 5142. A mounting groove 5111 is formed at the center of the second end of the connector 511 away from the second side of the second buffer platform 300. The first end of the pin 5142 is rotatably disposed within the mounting groove 5111 via the first rotating shaft. The second end of the pin 5142 is connected to the driving end of the first driver 520. Thus, when the first driver 520 drives the pin 5142 to move upward, the first rotating shaft will be displaced within the mounting groove 5111, allowing the first rotating shaft to be positioned within the mounting groove 5111. The first preset position of the connector 511 causes the pressing part 512 of the connector 511 to move in a direction close to the second buffer platform 300, thereby pressing the pressing part 512 against the multiple reagent strips 600 in the placement groove 310. When the first driver 520 drives the pin 5142 to move downward, the first rotating shaft will be displaced in the mounting groove 5111 and located in the second preset position of the mounting groove 5111, thereby causing the pressing part 512 of the connector 511 to move in a direction away from the second buffer platform 300, thereby releasing the multiple reagent strips 600 in the placement groove 310.
[0044] In addition, the first rotating shaft is rotatably disposed in the mounting groove 5111 to ensure the tight connection between the connector 511 and the second rotating part 514.
[0045] like Figure 4 and Figure 5 As shown, in one embodiment, a through hole is formed at the second end of the connector 511 on the second side away from the second buffer platform 300, and a rotation groove 5143 is formed in the middle of the second rotating part 514. The first rotating shaft passes through the through hole, the rotation groove 5143, and the mounting groove 5111 in sequence, and is fixed by a locking member, such as a nut, to fix both ends of the first rotating shaft. Of course, the operator can also choose other existing technologies to fix the first rotating shaft, such as fixing with a pin. Therefore, it is not specifically described in this disclosure.
[0046] In one embodiment, the rotating groove 5143 is a waist-shaped groove, and the extension direction of the waist shape is perpendicular to the driving direction of the first driver 520, so as to ensure that the clamping member 510 can be rotated open under the driving action of the first driver 520, thereby realizing the clamping or loosening of the reagent strip 600.
[0047] In one embodiment, the first rotating part 513 further includes a second rotating shaft 5131, and the second buffer platform 300 has a fastening groove formed on one side corresponding to the first rotating part 513. The first rotating part 513 is rotatably disposed in the fastening groove through the second rotating shaft 5131, so as to realize the rotational setting of the first rotating part 513 and the second buffer platform 300, so as to ensure that the clamping member 510 can rotate and open with the second buffer platform 300 under the action of the first driver 520.
[0048] In one embodiment, the second buffer platform 300 has a clearance groove on one side corresponding to the second rotating part 514 to ensure that the clamping member 510 will not collide with the second buffer platform 300 when it rotates and opens, thereby ensuring the reliable stability and safety of the operation of the clamping member 510.
[0049] like Figure 5 As shown, in one embodiment, the number of the first rotating parts 513 is at least two to ensure the reliable and stable operation of the clamping member 510.
[0050] It is understandable that, given the relatively light weight of the reagent strip 600 and the fact that its surface typically contains certain active pharmaceutical ingredients, excessive pressure from the first pressing component could easily damage the reagent strip 600. Figure 6 As shown, in one embodiment, the pressing part 512 has a plurality of pressing teeth 5122 on the side facing the second buffer platform 300. The pressing teeth 5122 are spaced apart and each pressing tooth 5122 corresponds to each placement groove 310. Each pressing tooth 5122 is used to press the corresponding reagent strip 600. In this way, while reducing the weight of the first pressing part, it also ensures that each pressing tooth 5122 can press the reagent strip 600 well.
[0051] like Figure 4 As shown, in one embodiment, each pressure tooth 5122 is adapted to the corresponding reagent strip 600 in the placement groove 310 to ensure that the pressing part 512 can effectively press the corresponding reagent strip 600 under the drive of the first driver 520. Specifically, those skilled in the art can adjust the positions of the pressure tooth 5122, the placement groove 310 and the reagent strip 600 according to the actual situation.
[0052] In one embodiment, the high-speed strip conveying and transfer table 10 further includes a second driver, a third driver 710, and a fourth driver 720. The drive end of the second driver is driven to the first buffer platform 200, and the second driver is used to drive the first buffer platform 200 to reciprocate along the horizontal direction of the frame 100; so as to realize the horizontal movement of the first buffer platform 200 in the frame 100, thereby ensuring that the first buffer platform 200 alternates between the working area 110 and the buffer zone 120; the drive end of the third driver 710 is driven to the first end of the second buffer platform 300. The third driver 710 is used to drive the second buffer platform 300 to reciprocate along the vertical direction of the frame 100, thereby realizing the raising and lowering of the second buffer platform 300 on the frame 100; the driving end of the fourth driver 720 is driven to be connected to the second end of the second buffer platform 300, and the fourth driver 720 is used to drive the second buffer platform 300 to reciprocate along the horizontal direction of the frame 100, thereby realizing the horizontal movement of the second buffer platform 300 on the frame 100, thereby ensuring that the second buffer platform 300 alternates between the working area 110 and the buffer zone 120.
[0053] It should be noted that when the first buffer platform 200 and the second buffer platform 300 need to alternate their movements, firstly, the first driver 520 drives the clamping member 510 to rise, so that the clamping member 510 clamps the reagent strip 600. Then, by controlling the third driver 710, the second buffer platform 300 is lowered. When the second buffer platform 300 has descended to a certain height, the second driver is then controlled to move the first buffer platform 200, so that the first buffer platform 200 is moved into the buffer zone 120 of the rack 100. Then, the control is controlled to move the first buffer platform 200 into the buffer zone 120 of the rack 100. The fourth actuator 720 moves the second buffer platform 300 to a position below the working area 110 of the rack 100. Then, the third actuator 710 raises the second buffer platform 300 and moves it into the working area 110 of the rack 100. Finally, the first actuator 520 drives the clamping member 510 to descend, causing the clamping member 510 to release the reagent strip 600. The above operation is repeated continuously to achieve the alternating movement of the first buffer platform 200 and the second buffer platform 300.
[0054] It should be noted that the connection structure for the second driver to control the horizontal movement of the first buffer platform 200 in the rack 100, the connection structure for the third driver 710 to control the vertical movement of the second buffer platform 300 in the rack 100, and the connection structure for the fourth driver 720 to control the horizontal movement of the second buffer platform 300 in the rack 100 can be obtained from existing technology. Therefore, they will not be described in detail in this disclosure.
[0055] In some other embodiments, the second buffer platform 300 moves horizontally back and forth along the frame 100, and the limiting component 500 is disposed on one side of the first buffer platform 200. The first buffer platform 200 moves horizontally and vertically back and forth along the frame 100 to achieve better limiting and fixing of the reagent strip 600 placed on the first buffer platform 200 when it moves vertically.
[0056] Of course, in some other embodiments, there are two limiting components 500, namely a first limiting component 500 and a second limiting component 500. The first limiting component 500 is disposed on one side of the first buffer platform 200; the second limiting component 500 is disposed on one side of the second buffer platform 300, so that the two additional limiting components 500 can respectively achieve better limiting and fixing of the reagent strip 600 of the first buffer platform 200 and the reagent strip 600 of the second buffer platform 300.
[0057] This disclosure also provides a high-speed strip-cutting conveyor 1, such as... Figure 7 and Figure 8 As shown, the high-speed strip-cutting conveyor 10 includes any of the embodiments described above. The high-speed strip-cutting conveyor 1 also includes a clamping and correcting conveying assembly 30, a strip-aligning and correcting conveying assembly, and a cutting assembly 20. The cutting assembly 20, the strip-aligning and correcting conveying assembly, and the clamping and correcting conveying assembly 30 are sequentially arranged on one side of the high-speed strip-cutting conveyor 10 to realize the batch alignment, correction, and conveying of multiple reagent strips 600 after the cutting assembly 20, thereby improving the conveying efficiency of the high-speed strip-cutting conveyor 1 and achieving a breakthrough in higher production capacity.
[0058] It should be noted that the cutting assembly 20, the clamping and straightening conveying assembly 30, and the strip straightening and conveying assembly are existing technologies, such as those implemented in Chinese Patent Document No. CN116986294A. Therefore, they will not be described in detail in this disclosure.
[0059] In a preferred embodiment, the cutting component 20 of the high-speed strip conveying device 1 has one cutting head, and the conveying component of the strip correction and handling component has a larger temporary storage capacity than the first buffer platform 200 or the second buffer platform 300, but is smaller than the sum of the storage capacities of the first buffer platform 200 and the second buffer platform 300. In this way, the continuous operation of one cutting head can be better achieved, thereby realizing a breakthrough in production capacity of 4000.
[0060] This disclosure also provides a reagent strip 600 production equipment, including the high-speed strip cutting and conveying transfer table 10 described in any of the above embodiments.
[0061] Compared with the prior art, this disclosure has at least the following advantages:
[0062] Since the limiting component 500 includes a clamping member 510 and a first driver 520, the clamping member 510 is rotatably disposed on one side of the first buffer platform 200 and / or the second buffer platform 300, and the first driver 520 is disposed on the first buffer platform 200 and / or the second buffer platform 300, the driving end of the first driver 520 is connected to the clamping member 510. The first driver 520 is used to drive the clamping member 510 to clamp the reagent strip 600 when the first buffer platform 200 and the second buffer platform 300 move alternately, so that the added limiting component 500 can achieve better fixation of the alternately moving reagent strip 600. In addition, the first driver 520 is also used to drive the clamping member 510 located in the working area 110 to release the reagent strip 600 so that the adsorption device 40 can adsorb it, thereby completing the batch rapid transfer operation, which not only improves the production efficiency of the reagent strip 600, but also effectively avoids the problem that the reagent strip 600 is prone to falling off when the traditional dual-station buffer platform is exchanged and moved.
[0063] The embodiments described above are merely illustrative of several implementations of this disclosure, and while the descriptions are specific and detailed, they should not be construed as limiting the scope of the disclosed patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this disclosure, and these all fall within the protection scope of this disclosure. Therefore, the protection scope of this patent should be determined by the appended claims.
Claims
1. A high-speed strip-cutting and conveying transfer table, comprising a frame, a first buffer platform, and a second buffer platform, wherein the frame forms an interconnected working area and a buffer zone; the first buffer platform and the second buffer platform are alternately and movably disposed between the working area and the buffer zone, and each of the first buffer platform and the second buffer platform forms a plurality of placement slots for placing reagent strips, characterized in that, The high-speed strip-cutting conveyor also includes a limiting component, which includes a clamping member and a first driver. The clamping member is rotatably disposed on one side of the first buffer platform and / or the second buffer platform. The first driver is disposed on the first buffer platform and / or the second buffer platform. The driving end of the first driver is connected to the clamping member. The first driver is used to drive the clamping member to clamp the reagent strip when the first buffer platform and the second buffer platform move alternately. The first driver is also used to drive the clamping member located in the working area to release the reagent strip.
2. The high-speed strip-cutting conveyor and transfer table according to claim 1, characterized in that, The first buffer platform moves horizontally back and forth along the frame, and the limiting component is disposed on one side of the second buffer platform. The second buffer platform moves horizontally back and forth and vertically back and forth along the frame.
3. The high speed slitting and conveying carousel according to claim 2, characterized in that, The clamping component includes a connector, a pressing part, a first rotating part, and a second rotating part. The pressing part is disposed at a first end of the connector. The first rotating part is disposed at a second end of the connector on a first side facing the second buffer platform. The second rotating part is disposed at a second end of the connector on a second side away from the second buffer platform. The second rotating part is connected to the driving end of the first driver. When the first driver drives the second rotating part to a first preset position, the pressing part clamps and fixes the reagent strip. When the first driver drives the second rotating part to a second preset position, the second pressing part releases the reagent strip.
4. The high speed slitting and conveying station according to claim 3, wherein, The pressing part, the connector, and the first rotating part are connected together to form a mounting cavity, which is used to accommodate the second buffer platform; the side of the pressing part facing the connector has a receiving cavity, which is in communication with the mounting cavity, and is used to accommodate the reagent strip.
5. The high speed slitting and conveying staging system of claim 3, wherein, The second rotating part includes a first rotating shaft and a pin. The second end of the connector has a mounting groove formed in the middle of the second side away from the second buffer platform. The first end of the pin is rotatably disposed in the mounting groove through the first rotating shaft. The second end of the pin is connected to the driving end of the first driver.
6. The high speed slitting and conveying staging system of claim 3, wherein, The first rotating part further includes a second rotating shaft, and the second buffer platform has a fastening groove formed on one side corresponding to the first rotating part. The first rotating part is rotatably disposed in the fastening groove by means of the second rotating shaft.
7. The high speed slitting and conveying staging system of claim 6, wherein, The number of the first rotating parts is at least two; and / or, The second buffer platform has a clearance groove formed on one side corresponding to the second rotating part; and / or, The pressing part has a plurality of pressing teeth on the side facing the second buffer platform. The pressing teeth are spaced apart and each pressing tooth corresponds to one of the placement grooves. Each pressing tooth is used to press the corresponding reagent strip.
8. The high speed slitting and conveying staging system of claim 1, wherein, The second buffer platform reciprocates horizontally along the frame, and the limiting component is disposed on one side of the first buffer platform. The first buffer platform reciprocates both horizontally and vertically along the frame; or, The number of limiting components is two, namely a first limiting component and a second limiting component. The first limiting component is disposed on one side of the first buffer platform; the second limiting component is disposed on one side of the second buffer platform.
9. A high speed slitting and conveying apparatus characterized by, The high-speed strip-cutting conveyor and transfer table includes any one of claims 1 to 8.
10. A reagent strip production device, characterized in that, Includes the high-speed strip-cutting conveyor and transfer table as described in claim 9.