A kit with a vibration anti-condensation structure

Abstract

The application discloses a kit with vibration anti-condensation structure and belongs to the technical field of biomedicine. The kit comprises a kit shell, a cover plate detachably arranged on the top of the kit shell, and a movable groove formed in the kit shell. A vibrating plate is movably arranged in the movable groove through elastic members arranged on the top and the bottom of the vibrating plate. A driving mechanism is arranged at the bottom of the vibrating plate and used for driving the vibrating plate to vibrate. A placing plate is detachably arranged on the top of the vibrating plate, a reagent groove is formed in the top of the placing plate, and a squeezing mechanism is arranged in the reagent groove and used for fixing a reagent bottle in the reagent groove. The squeezing mechanism is adopted, the reagent bottle is fixed through cooperation of the squeezing mechanism, the problem that the reagent bottle slides at a placing gap during vibration and affects vibration anti-condensation is solved, and the effect that the reagent bottle is placed stably during vibration is realized.

Description

Technical Field

[0001] This application relates to the field of biomedical technology, and more specifically, to a reagent kit with a vibration-induced anticoagulation structure. Background Technology

[0002] A reagent kit is a special container used for storing, managing, and using reagent bottles. It typically contains pre-packaged reagents, standards, buffer solutions, and other essential experimental components. It not only ensures the stability and effectiveness of the reagents but also improves the standardization and convenience of experimental procedures.

[0003] In related technologies, in order to solve the problem of reagents easily solidifying in the reagent kit during long-term storage, for example, the patent with prior art publication number CN206954773U provides a reagent kit with vibration anti-coagulation function. By using this device, the liquid test reagents stored in the device can be vibrated at regular intervals to prevent the liquid test reagents from solidifying, making it easier for medical staff to take out the liquid test reagents in the device and effectively improving the work progress of medical staff.

[0004] Although the existing technical solutions mentioned above have solved the problem of reagent solidification during long-term storage by using a support plate that vibrates up and down, there is usually a certain gap at the connection between the two in order to facilitate the placement of the reagent bottle in the reagent kit. When the reagent bottle is vibrating, it will slide at the gap, which will not only eliminate part of the anti-coagulation effect of vibration, but also generate greater wear and noise when the reagent bottles collide with each other.

[0005] In view of this, we propose a kit with a vibration-based anti-condensation structure. Utility Model Content

[0006] The purpose of this application is to provide a reagent kit with a vibration-resistant anti-coagulation structure, which can effectively solve the problem in the prior art where the reagent bottle slides in the placement gap during vibration, thus affecting the vibration-resistant anti-coagulation, and achieves the effect of stabilizing the placement of the reagent bottle during vibration.

[0007] This application provides a kit with a vibration-induced anti-coagulation structure, comprising:

[0008] The reagent kit housing has a detachable cover plate on the top and a movable groove inside the housing.

[0009] A vibrating plate, wherein the vibrating plate is movably disposed inside a movable groove by elastic members at the top and bottom;

[0010] A driving mechanism is provided at the bottom of the vibrating plate and is used to drive the vibrating plate to vibrate.

[0011] A placement plate is detachably mounted on top of a vibrating plate. A reagent slot is provided on the top of the placement plate, and a squeezing mechanism is provided inside the reagent slot to fix the reagent bottle inside the reagent slot.

[0012] As an optional solution to the technical solution of this application, the reagent tank has several openings on the top of the placement plate, and the several placement plates have multiple levels of hole diameter. The placement plate includes an elastic plastic fixed to the inner wall of the reagent tank, and a squeezing plate is fixed to the end of the elastic plastic. The squeezing plate is semi-circular and used to hold the reagent bottle.

[0013] As an optional solution to the technical solution of this application, the driving mechanism includes a timer fixed to the outer wall of the reagent kit shell, a battery is provided at the end of the timer and the battery is fixedly connected to the bottom of the reagent kit shell, a vibration motor is provided at the end of the battery and the vibration motor is fixedly connected to the bottom of the vibration plate; both the vibration motor and the timer are electrically connected to the control module.

[0014] As an optional solution to the technical solution of this application, the placement plate has inner grooves on both sides, and elastic buckles are fixed to the inner walls of the inner grooves. The bottom of the elastic buckles is a sloping structure. The inner walls of the vibration plate are provided with fixing grooves corresponding to the elastic buckles, and the sloping structure of the elastic buckles is located on one side of the fixing groove.

[0015] As an optional solution to the technical solution of this application, the vibration plate has two top columns slidably connected in the middle, a push plate is fixedly connected to the end of the top column, and a protective pad is fixedly connected to the other end of the top column; the protective pad is located on one side of the fixed groove and is used to push the elastic buckle inclined into the inner groove.

[0016] As an optional solution to the technical solution of this application, a placement pad is fixedly attached to the bottom corner of the reagent kit shell.

[0017] As an optional solution to the technical solution of this application, the top of the extrusion plate has a sloping structure, and a rubber pad is provided on the side of the extrusion plate near the reagent bottle.

[0018] One or more technical solutions provided in the embodiments of this application have at least the following technical effects or advantages:

[0019] (1) This application uses a squeezing mechanism to fix the reagent bottle, which solves the problem that the reagent bottle slides in the gap during vibration and affects the vibration anti-coagulation, thus achieving the effect of stable placement of the reagent bottle during vibration.

[0020] (2) This application uses a protruding elastic buckle to fix the placement plate after the end of the elastic buckle is completely closed with the fixing groove. At the same time, pushing the top of the elastic buckle can also complete the disassembly. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of the overall structure of a reagent kit with a vibration-anti-coagulation structure disclosed in a preferred embodiment of this application;

[0022] Figure 2 This is a cross-sectional schematic diagram of a reagent kit with a vibration-anti-coagulation structure disclosed in a preferred embodiment of this application;

[0023] Figure 3 for Figure 2 Enlarged view of point A;

[0024] Figure 4 This is a schematic diagram of the placement plate structure of the reagent kit with a vibration-anti-coagulation structure disclosed in a preferred embodiment of this application;

[0025] The following are the labels in the diagram: 1. Reagent kit shell; 11. Cover plate; 12. Movable groove; 13. Placement pad; 2. Vibrating plate; 21. Vibrating motor; 22. Fixing groove; 3. Drive mechanism; 31. Timer; 32. Battery; 4. Placement plate; 41. Reagent tank; 42. Squeezing mechanism; 43. Elastic plastic; 44. Squeezing plate; 5. Inner groove; 51. Elastic buckle; 6. Top column; 61. Push plate; 62. Protective pad; 100. Reagent bottle. Detailed Implementation

[0026] The present application will be further described in detail below with reference to the accompanying drawings.

[0027] Reference Figures 1-4This application discloses a reagent kit with a vibration anti-coagulation structure, comprising a reagent kit shell 1, a vibration plate 2, a driving mechanism 3, and a placement plate 4. The top of the reagent kit shell 1 is detachably fitted with a cover plate 11, and a movable groove 12 is formed inside the shell 1. The vibration plate 2 is movably disposed inside the movable groove 12 via elastic elements (such as elastic sheets, springs, etc.) at the top and bottom, with its four sides in contact with the inner wall of the movable groove 12. The driving mechanism 3 is disposed at the bottom of the vibration plate 2 and is used to drive the vibration plate 2 to vibrate. The placement plate 4 is detachably disposed at the top of the vibration plate 2 and is used to place... A reagent slot 41 is provided on the top of the plate 4. A squeezing mechanism 42 is provided inside the reagent slot 41 to fix the reagent bottle 100 in the reagent slot 41. The driving mechanism 3 includes a timer 31 fixed to the outer wall of the reagent kit housing 1. A storage battery 32 is provided at the end of the timer 31 and is fixed to the bottom of the reagent kit housing 1. A vibration motor 21 is provided at the end of the storage battery 32. The vibration motor 21 is fixedly connected to the bottom of the vibration plate 2. Both the vibration motor 21 and the timer 31 are electrically connected to the control module. Placement pads 13 are fixedly attached to the bottom corners of the reagent kit housing 1.

[0028] The reagent kit housing 1 needs to be placed on the worktable so that multiple placement pads 13 are in contact with the placement table. The reagent liquid to be stored can then be poured into the reagent bottle 100 and sealed. The cover 11 is then opened, and the reagent bottle 100 can be placed in the reagent slot 41. The squeezing mechanism 42 secures the placed reagent bottle 100. Subsequently, with the assistance of the drive mechanism 3, after the preset time of the timer 31, the battery 32 continuously supplies power to the timer 31 and the vibration motor 21, causing the vibrating plate 2 to move upwards at the movable slot 12. The vibration of the vibrating plate 2 simultaneously moves the reagent and disperses the liquid reagent to be solidified in the reagent bottle 100. This step, with the intermittent vibration of the vibrating plate 2, prevents the liquid in the reagent bottle 100 from solidifying. At the same time, with the squeezing mechanism 42 fixing the reagent bottle 100, the problem of the reagent bottle 100 sliding in the placement gap during vibration and affecting the vibration anti-coagulation is solved. This achieves a stable placement effect for the reagent bottle 100 during vibration. In addition, the multiple placement pads 13 reduce the stability of the reagent kit shell 1 on the worktable.

[0029] Reference Figure 3Based on the above embodiments, in order to fix the reagent bottle 100 in the reagent tank 41 and achieve a stable placement effect when the reagent bottle 100 vibrates, specifically, the reagent tank 41 has several openings on the top of the placement plate 4, and the hole diameters of the several placement plates 4 are set in multiple levels. The placement plate 4 includes an elastic plastic 43 fixed to the inner wall of the reagent tank 41, and a compression plate 44 is fixed to the end of the elastic plastic 43. The compression plate 44 is semi-circular and used to clamp the reagent bottle 100; a reagent bottle 100 of a specified size can be placed in the corresponding reagent tank 41, and the reagent bottle 100 When placed, the bottom of the reagent bottle 100 can be squeezed towards the reagent tank 41, causing the length of the elastic plastic 43 to change. After the reagent bottle 100 is fully placed, the elasticity of the elastic plastic 43 and the wrapping of the squeezing plate 44 can fix the reagent bottles 100 of different sizes. This step, in conjunction with the elastic plastic 43, fills the gaps in the placement, which can achieve the stability of the reagent bottle 100 when placed. Moreover, the reagent tank 41 of different sizes can accommodate reagent bottles 100 of different sizes, improving the flexibility of reagent bottle 100 storage.

[0030] Reference Figure 2 and Figure 4 Both sides of the placement plate 4 are provided with inner grooves 5. The inner wall of the inner groove 5 is fixed with an elastic buckle 51. The bottom of the elastic buckle 51 is a sloping structure. The inner wall of the vibration plate 2 is provided with a fixing groove 22 corresponding to the elastic buckle 51. The sloping structure of the elastic buckle 51 is located on one side of the fixing groove 22. Two top columns 6 are slidably connected in the middle of the vibration plate 2. The end of the top column 6 is fixed with a push plate 61, and the other end of the top column 6 is fixed with a protective pad 62. The protective pad 62 is located on one side of the fixing groove 22 and is used to push the sloping surface of the elastic buckle 51 into the inner groove 5.

[0031] When the placement plate 4 needs to be pressed downwards against the inner wall of the vibrating plate 2, the inclined surfaces of the two unfolded elastic buckles 51 can first contact the inner wall of the vibrating motor 21, so that the elastic buckles 51 can move towards the inner groove 5 after being squeezed. After the placement plate 4 is pressed down until it reaches the bottom, the protruding part of the fixing groove 22 can be locked into the inner wall of the fixing groove 22 under the action of elastic force, thus completing the overall fixation of the placement plate 4. Subsequently, the two push plates 61 can be pushed in sequence, so that the protective pad 62 can once again lock the elastic buckles 51. Press the protruding end to the inner groove 5 position and pull up the placement plate 4 to remove it. This step, together with the elastic buckle 51 with the protrusion, allows the end of the elastic buckle 51 to be completely closed with the fixing groove 22, thereby fixing the placement plate 4. At the same time, pushing the top position of the elastic buckle 51 can also complete the disassembly. Under the action of the sliding top column 6, the bottom part of the elastic buckle 51 can be pressed to facilitate the overall disassembly of the placement plate 4. With the effect of the protective pad 62, the damage caused by the pressing can be reduced.

[0032] Reference Figure 3 The top of the squeezing plate 44 has a sloping structure, and a rubber pad is provided on one side of the squeezing plate 44 that squeezes the reagent bottle 100. When the reagent bottle 100 is transferred to the reagent tank 41, its bottom can first contact the sloping top of the squeezing plate 44. When the squeezing plate 44 fixes the reagent bottle 100, the rubber pad on the squeezing plate 44 can directly contact the outer wall of the reagent bottle 100. This step, under the action of the sloping structure of the squeezing plate 44, can reduce the number of times the reagent bottle 100 is stuck. At the same time, with the rubber pad, the stability of the reagent bottle 100 when placed is further increased.

[0033] In summary, when using the reagent kit with vibration anti-coagulation structure disclosed in this application embodiment, the reagent kit shell 1 needs to be placed on a workbench so that multiple placement pads 13 are in contact with the placement bench. The reagent liquid to be stored can then be poured into the reagent bottle 100 and sealed. The cover 11 is then opened, and the reagent bottle 100 can be placed in the reagent slot 41. The squeeze mechanism 42 secures the placed reagent bottle 100. Subsequently, with the help of the drive mechanism 3, after the preset time of the timer 31, the battery 32 continuously supplies power to the timer 31 and the vibration motor 21, causing the vibrating plate 2 to vibrate up and down at the movable slot 12, simultaneously moving the reagent and shaking to evenly disperse the reagent liquid to be coagulated in the reagent bottle 100. Reagent bottles 100 of a specified size can be placed in the corresponding reagent slot 41, and when placed, the bottom of the reagent bottle 100 can be squeezed towards one side of the reagent slot 41, causing a change in the length of the elastic plastic 43. Subsequently, the reagent bottle... Once fully inserted, the elasticity of the elastic plastic 43 and the encapsulation of the compression plate 44 allow for the fixation of reagent bottles 100 of different sizes. When the placement plate 4 needs to be pressed downwards against the inner wall of the vibrating plate 2, the inclined surfaces of the two unfolded elastic buckles 51 will first contact the inner wall of the vibrating motor 21, causing the elastic buckles 51 to be compressed and move towards the inner groove 5. After the placement plate 4 is pressed down until it reaches the bottom, the protruding part of the fixing groove 22 will be locked in place under the action of elasticity. The inner wall of the fixing groove 22 is fixed, and the entire placement plate 4 is fixed. Subsequently, the two push plates 61 can be pushed in sequence so that the protective pad 62 presses the protruding end of the elastic buckle 51 to the inner groove 5 position again, and the placement plate 4 can be pulled up to remove it. When the reagent bottle 100 is transferred to the reagent groove 41, its bottom can first contact the top inclined surface of the squeezing plate 44, and when the squeezing plate 44 fixes the reagent bottle 100, the rubber pad on the squeezing plate 44 can directly contact the outer wall of the reagent bottle 100.

Claims

1. A reagent kit with a vibration-induced anti-coagulation structure, characterized in that, Include: The reagent kit housing (1) has a cover plate (11) detachably provided on the top of the reagent kit housing (1), and a movable groove (12) is provided inside the reagent kit housing (1); Vibrating plate (2), the vibrating plate (2) is movably disposed inside the movable groove (12) by elastic members at the top and bottom; A driving mechanism (3) is provided at the bottom of the vibrating plate (2) and is used to drive the vibrating plate (2) to vibrate. Placement plate (4), which is detachably mounted on the top of vibration plate (2), has a reagent tank (41) on the top of the placement plate (4), and a squeezing mechanism (42) is provided inside the reagent tank (41) to fix the reagent bottle (100) in the reagent tank (41).

2. The reagent kit with a vibration-induced anti-coagulation structure according to claim 1, characterized in that: The reagent tank (41) has several openings on the top of the placement plate (4), and the holes of the several placement plates (4) are set in multiple levels. The placement plate (4) includes an elastic plastic (43) fixed to the inner wall of the reagent tank (41). The end of the elastic plastic (43) is fixed with a squeezing plate (44), which is semi-circular and used to hold the reagent bottle (100).

3. The reagent kit with a vibration-induced anti-coagulation structure according to claim 1, characterized in that: The driving mechanism (3) includes a timer (31) fixed to the outer wall of the reagent kit housing (1). A battery (32) is provided at the end of the timer (31), and the battery (32) is fixed to the bottom of the reagent kit housing (1). A vibration motor (21) is provided at the end of the battery (32). The vibration motor (21) is fixedly connected to the bottom of the vibration plate (2). Both the vibration motor (21) and the timer (31) are electrically connected to the control module.

4. The reagent kit with a vibration-induced anti-coagulation structure according to claim 1, characterized in that: The placement plate (4) has an inner groove (5) on both sides. An elastic buckle (51) is fixed to the inner wall of the inner groove (5). The bottom of the elastic buckle (51) is a sloping structure. The inner wall of the vibration plate (2) is provided with a fixing groove (22) corresponding to the elastic buckle (51). The sloping structure of the elastic buckle (51) is located on one side of the fixing groove (22).

5. The reagent kit with a vibration-induced anti-coagulation structure according to claim 4, characterized in that: Two top columns (6) are slidably connected in the middle of the vibration plate (2). A push plate (61) is fixed to the end of the top column (6), and a protective pad (62) is fixed to the other end of the top column (6). The protective pad (62) is located on one side of the fixed groove (22) and is used to push the elastic buckle (51) into the inner groove (5) at an angle.

6. The reagent kit with a vibration-induced anti-coagulation structure according to claim 1, characterized in that: Placement pads (13) are fixed to the bottom corners of the reagent kit housing (1).

7. The reagent kit with a vibration-induced anti-coagulation structure according to claim 2, characterized in that: The top of the extrusion plate (44) is a sloping structure, and a rubber pad is provided on the side of the extrusion plate (44) near the reagent bottle (100).

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