A bottle disassembly and assembly structure for a bottle shaker
By designing a stepped surface and a sliding plate structure on the bottle shaking machine, and with the sliding plate cooperating with the locking device, the problem of low bottle disassembly and assembly efficiency in the existing technology is solved, and efficient operation of simultaneous bottle disassembly and assembly is achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 宁波博恒质量技术服务有限公司
- Filing Date
- 2025-05-23
- Publication Date
- 2026-06-30
AI Technical Summary
The existing bottle-disassembly and assembly structure of the shaker has low efficiency in disassembling and assembling bottles during large-scale testing, and opening and clamping bottles one by one is inefficient.
The design features a stepped surface and a sliding plate on the rocking plate. The sliding plate is equipped with a second semi-conical fastener. The sliding plate is fixed to the stepped surface through a locking device. Multiple second semi-conical fasteners are opened or locked simultaneously when the sliding plate slides.
It enables the simultaneous opening or fastening of multiple second semi-conical fasteners, improving the efficiency of bottle assembly and disassembly and avoiding interference between bottles.
Smart Images

Figure CN224430564U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of bottle shaker technology, and more specifically to a bottle disassembly and assembly structure for a bottle shaker. Background Technology
[0002] In the process of microbial research, it is necessary to shake the culture flasks to ensure that the culture medium is fully mixed with oxygen, which is conducive to the cultivation of microorganisms. To achieve the shaking of the culture flasks, shakers are often used.
[0003] There is a bottle-disassembly and assembly structure for a bottle shaker, such as Figure 1 As shown, the device includes a shaking plate 90, on which a plurality of first semi-conical fasteners 91 arranged at intervals are fixedly connected, and a plurality of second semi-conical fasteners 92 are rotatably mounted on the shaking plate 90. The first semi-conical fasteners 91 and the second semi-conical fasteners 92 correspond one-to-one. A gate 93 is rotatably mounted on one side of each second semi-conical fastener 92, and a slot 921 is provided on one side of the second semi-conical fastener 92. When placing a culture bottle, one side of the culture bottle is placed in the first semi-conical fastener 91, and the second semi-conical fastener 92 is rotated at a predetermined angle to abut against the first semi-conical fastener 91. At this time, the bottom side of the culture bottle is clamped by the first semi-conical fastener 91 and the second semi-conical fastener 92. Then, the gate 93 is rotated at a predetermined angle and inserted into the slot 921 to fix the culture bottle. However, the above-mentioned bottle disassembly and assembly structure involves opening and clamping the bottles one by one, which is inefficient in large-scale testing.
[0004] Therefore, there is a need for a bottle disassembly and assembly structure for a shaker that can simultaneously open or fasten multiple second semi-conical fasteners, resulting in higher efficiency in disassembling and assembling bottles. Summary of the Invention
[0005] The main objective of this application is to provide a bottle disassembly and assembly structure for a bottle shaker, comprising a housing. The structure includes a shaking disc and several locking devices. The shaking disc is horizontally movably mounted on the housing. The shaking disc has multiple stepped surfaces, each with multiple spaced-apart first semi-conical fasteners. A sliding plate is slidably disposed on each stepped surface, with multiple spaced-apart second semi-conical fasteners on the sliding plate. The first and second semi-conical fasteners are arranged opposite to each other. When the sliding plate slides, the second semi-conical fasteners abut or separate from the first semi-conical fasteners. The locking devices are used to fix the relative position of the sliding plate to the corresponding stepped surface. By connecting the sliding plate to multiple second semi-conical fasteners, when it is necessary to abut or separate the second semi-conical fasteners from the first semi-conical fasteners, only the sliding plate needs to be moved. Compared with the prior art, this method has the advantage of simultaneously opening or fastening multiple second semi-conical fasteners, resulting in higher bottle disassembly and assembly efficiency.
[0006] Another objective of this application is to provide a bottle disassembly and assembly structure for a bottle shaker, wherein each of the stepped surfaces has a first extension end at both ends, the first extension end comprising a horizontal section and a vertical section, and each of the sliding plates has a second extension end at both ends, each of the second extension ends having a guide portion slidably disposed on the horizontal section, the guide portion having a slot, and each locking device comprising a rod member threadedly connected to the vertical section. When the rod member rotates at a predetermined angle, the rod member engages or disengages from the slot. The end of the rod member facing away from the second extension end has a material removal notch, the material removal notch extending to one side of the slot, and making the highest point on one side of the slot lower than the highest point on the other side of the slot. By setting the material removal notch, the sliding plate can be quickly pulled out when the rod member separates from the bottom wall of the slot.
[0007] To achieve at least one of the above-mentioned inventive objectives, this application provides a bottle disassembly and assembly structure for a shaker, comprising a housing, wherein the bottle disassembly and assembly structure for the shaker includes:
[0008] A rocking disc, horizontally movably mounted on the housing, the rocking disc having multiple stepped surfaces, each stepped surface having multiple spaced-apart first semi-conical fasteners, and each stepped surface having a sliding plate slidably disposed thereon, the sliding plate having multiple spaced-apart second semi-conical fasteners, the first semi-conical fasteners and the second semi-conical fasteners being arranged opposite to each other, and when the sliding plate slides, the second semi-conical fasteners abut against or separate from the first semi-conical fasteners; and
[0009] Several locking devices for fixing the relative position of the sliding plate and the corresponding step surface.
[0010] In one or more embodiments of this application, each of the stepped surfaces has a first extension end at both ends, the first extension end including a horizontal section and a vertical section, each of the sliding plates has a second extension end at both ends, each of the second extension ends has a guide portion, the guide portion is slidably disposed on the horizontal section, the guide portion has a slot, each of the locking devices includes a rod, the rod is threadedly connected to the vertical section, and when the rod rotates a predetermined angle, the rod engages or disengages from the slot.
[0011] In one or more embodiments of this application, each of the locking devices further includes a plug arm, the end of the rod opposite to the guide portion having a first groove, the top surface of the second extension end having a second groove, and the two ends of the plug arm having an insertion portion and a gripping portion respectively, the insertion portion being inserted into the first groove or the second groove.
[0012] In one or more embodiments of this application, the end of the rod opposite to the second extension end has a material removal notch, the material removal notch extends to one side of the slot, and the highest point on one side of the slot is lower than the highest point on the other side of the slot.
[0013] In one or more embodiments of this application, the slot has an inclined surface on the side near the material removal notch, and the rod abuts against or separates from the inclined surface.
[0014] In one or more embodiments of this application, the sliding plate on one of the stepped surfaces has a plurality of guide grooves on the side near the adjacent step surface, and a plurality of guide rods are vertically arranged on a step surface adjacent to the guide grooves, the guide rods being slidably disposed in the guide grooves.
[0015] In one or more embodiments of this application, a threaded fastener is provided at one end of the guide portion of the sliding plate having the material removal notch, and the threaded fastener abuts against the horizontal section after the sliding plate slides a predetermined distance.
[0016] In one or more embodiments of this application, the housing further has a receiving cavity, and the bottle disassembly and assembly structure for the shaker further includes a motor and an eccentric component. The motor is placed in the receiving cavity, the rotating shaft of the motor is fixedly connected to one end of the eccentric component, and the other end of the eccentric component is connected to the shaking disk.
[0017] In this embodiment, the bottle disassembly and assembly structure for the shaker includes a housing, a shaking disc, and several locking devices. The shaking disc is horizontally movably mounted on the housing. The shaking disc has multiple stepped surfaces, each with multiple first semi-conical fasteners. A sliding plate is slidably mounted on each stepped surface, with multiple second semi-conical fasteners on the sliding plate. The first and second semi-conical fasteners are arranged opposite to each other. When the sliding plate slides, the second semi-conical fasteners abut or separate from the first semi-conical fasteners. The locking devices are used to fix the relative position of the sliding plate and the corresponding stepped surface. By connecting the sliding plate to multiple second semi-conical fasteners, when it is necessary to abut or separate the second semi-conical fasteners from the first semi-conical fasteners, only the sliding plate needs to be moved. Compared with the prior art, this has the advantage of simultaneously opening or fastening multiple second semi-conical fasteners, resulting in higher bottle disassembly and assembly efficiency. Attached Figure Description
[0018] These and / or other aspects and advantages of this application will become clearer and more readily understood from the following detailed description of embodiments of this application taken in conjunction with the accompanying drawings, wherein:
[0019] Figure 1 The diagram illustrates a structural schematic of a bottle assembly / disassembly structure for a conventional bottle shaker.
[0020] Figure 2 The figure shows a schematic diagram of the bottle assembly / disassembly structure for a shaker according to this application at a certain angle;
[0021] Figure 3 The diagram illustrates the structure of the rocker plate with a sliding plate at another angle.
[0022] Figure 4 The diagram illustrates the structure of the rocking disc at another angle.
[0023] Figure 5 The diagram shows... Figure 3 A magnified view of a portion of point C. Detailed Implementation
[0024] The terms and words used in the following specification and claims are not limited to their literal meaning, but are used solely by the inventors to enable a clear and consistent understanding of this application. Therefore, it will be apparent to those skilled in the art that the following description of various embodiments of this application is provided for illustrative purposes only and not for the purpose of limiting the application as defined in the appended claims and their equivalents.
[0025] It is understood that the term "a" should be understood as "at least one" or "one or more", that is, in one embodiment, the number of an element can be one, while in another embodiment, the number of the element can be multiple, and the term "a" should not be understood as a limitation on the number.
[0026] While ordinal numbers such as "first," "second," etc., will be used to describe various components, there is no limitation on which components are used herein. The term is used only to distinguish one component from another. For example, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component, without departing from the teachings of the utility model concept. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.
[0027] The terminology used herein is for the purpose of describing various embodiments only and is not intended to be limiting. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. It will also be understood that the terms “comprising” and / or “having” as used in this specification specify the presence of the described features, numbers, steps, operations, components, elements or combinations thereof, without excluding the presence or addition of one or more other features, numbers, steps, operations, components, elements or groups thereof.
[0028] Indicative bottle-mounting and disassembling structure for a bottle shaker, for reference. Figures 2 to 5 According to a preferred embodiment of the present invention, a bottle disassembly and assembly structure for a bottle shaker includes a housing 10 and a shaking disk 20, wherein the shaking disk 20 is horizontally movably disposed on the housing 10.
[0029] Specifically, to achieve the horizontal movement of the rocking disk 20, such as Figure 2 As shown, the housing 10 also has a receiving cavity 101. The bottle disassembly and assembly structure for the shaker also includes a motor 30 and an eccentric component 301. The motor 30 is placed inside the receiving cavity 101. The rotating shaft of the motor 30 is fixedly connected to one end of the eccentric component 301, and the other end of the eccentric component 301 is connected to the shaking disk 20.
[0030] It should be noted that when the shaft of the motor 30 moves, the rocking disk 20 moves horizontally.
[0031] Furthermore, such as Figures 2 to 4 As shown, the shaking disc 20 has multiple stepped surfaces 201, each stepped surface 201 has multiple spaced-apart first semi-conical fasteners 2011, and each stepped surface 201 has a sliding plate 202 slidably disposed thereon, the sliding plate 202 has multiple spaced-apart second semi-conical fasteners 2021, the first semi-conical fasteners 2011 and the second semi-conical fasteners 2021 are arranged opposite to each other, when the sliding plate 202 slides, the second semi-conical fasteners 2021 abut against or separate from the first semi-conical fasteners 2011, the bottle shaking machine bottle disassembly and assembly structure also includes several locking devices 40 for fixing the relative positions of the sliding plate 202 and the corresponding stepped surfaces 201.
[0032] It should be noted that, in this embodiment, the rocking disc 20 has two stepped surfaces 201, and the platforms of the two stepped surfaces 201 are spaced apart by a predetermined distance in the height direction, as shown in the reference. Figure 4Furthermore, each of the two stepped surfaces 201 has a notch 2012 at its front end. The sliding plate 202 is slidably disposed on the notch 2012, and the top surface of the sliding plate 202 is flush with the stepped surface 201. It should also be emphasized that the lowest point of the inner conical hole of the first semi-conical fastener 2011 and the second semi-conical fastener 2021 extends to the bottom surface of the notch 2012. Assuming that no culture bottle is placed between the first semi-conical fastener 2011 and the second semi-conical fastener 2021 at this time, and the first semi-conical fastener 2011 and the second semi-conical fastener 2021 abut against each other, it should be noted that the bottom of the culture bottle is conical. At this time, the operator needs to place multiple of the culture bottles... With the culture flask mounted on the shaking plate 20, the operator only needs to move the sliding plate 202 on one of the stepped surfaces 201 a predetermined distance away from the stepped surface 201. Since each of the second semi-conical fasteners 2021 is fixedly connected to the sliding plate 202, each of the second semi-conical fasteners 2021 on the sliding plate 202 moves away from the corresponding first semi-conical fastener 2011, so that the operator can place the culture flask on the bottom surface of the notch 2012. It should be noted that at this time, half of the sidewall of the culture flask is in contact with the wall of the inner conical hole of the first semi-conical fastener 2011. Subsequently, the operator moves the sliding plate 202 towards the bottom surface of the notch 2012. The first semi-conical fastener 2011 moves in one direction, causing the second semi-conical fastener 2021 to abut against the first semi-conical fastener 2011. At this time, the bottom sidewall of the culture bottle is in contact with the inner conical hole walls of the first semi-conical fastener 2011 and the second semi-conical fastener 2021, respectively. Subsequently, the locking device 40 fixes the relative position of the sliding plate 202 and the step surface 201. At this time, the first semi-conical fastener 2011 and the second semi-conical fastener 2021 clamp the culture bottle, preventing the culture bottle from falling out when the shaking plate 20 moves horizontally. It is evident that, compared to the prior art where the second semi-conical fastener 2021 is moved one by one, this application achieves this by designing... The sliding plate 202 is positioned and simultaneously connected to multiple second semi-conical fasteners 2021. This allows the multiple second semi-conical fasteners 2021 to abut or separate from the corresponding first semi-conical fasteners 2011 when the sliding plate 202 is moved. This provides the advantage of simultaneously opening or fastening multiple second semi-conical fasteners 2021, resulting in higher efficiency in bottle assembly and disassembly. In addition, since the diameter of the upper bottle opening of the culture bottle is small, by setting two stepped surfaces 201 of different heights, interference between the sliding plate 202 at the higher position and the culture bottle on the stepped surface 201 at the lower position is effectively avoided when both sliding plates 202 are pulled outward.
[0033] Furthermore, to enable the sliding plate 202 to slide on the step surface 201, as follows: Figure 3 and Figure 5 As shown, each of the stepped surfaces 201 has a first extension end 2013 at both ends. The first extension end 2013 includes a horizontal section 20131 and a vertical section 20132. Each of the sliding plates 202 has a second extension end 2022 at both ends. Each second extension end 2022 has a guide portion 2023. The guide portion 2023 is slidably disposed on the horizontal section 20131. The guide portion 2023 has a slot 20231. Each locking device 40 includes a rod 401. The rod 401 is threadedly connected to the vertical section 20132. When the rod 401 rotates at a predetermined angle, the rod 401 is engaged with or disengaged from the slot 20231.
[0034] It should be noted that when the second semi-conical fastener 2021 abuts against the first semi-conical fastener 2011 and fits against the bottom side wall of the culture bottle, the operator can screw the rod 401 and make the rod 401 extend into the slot 20231 and press against the bottom wall of the slot 20231 to fix the sliding plate 202 to the step surface 201, thereby clamping the culture bottle with the second semi-conical fastener 2021 and the first semi-conical fastener 2011.
[0035] Furthermore, to facilitate the rotation of the rod 401, as follows: Figure 5 As shown, each of the locking devices 40 further includes a insert arm 402, and the end of the rod 401 facing away from the guide portion 2023 has a first groove 4011, such as... Figure 3 As shown, the top surface of the second extension end 2022 has a second groove 20222, and the two ends of the insertion arm 402 have an insertion part 4021 and a gripping part 4022, respectively. The insertion part 4021 is inserted into the first groove 4011 or the second groove 20222.
[0036] It should be noted that when the rod 401 needs to be rotated, the insertion part 4021 of the insert arm 402 is inserted into the first groove 4011, and then the gripping part 4022 is held and the insert arm 402 is rotated. Since the first groove 4011, the second groove 20222 and the insert plate are all square or regular hexagonal, the insert arm 402 provides an extended lever arm to drive the rod 401 to rotate circumferentially in a labor-saving manner, and to make the rod 401 engage or disengage from the slot 20231. In addition, a magnet is embedded in the bottom of both the first groove 4011 and the second groove 20222. Before the rocking disc 20 moves, the operator can first insert the insertion part 4021 of the insert arm 402 into the corresponding second groove 20222 and attract it with the magnet. At the same time, the side wall of the insert arm 402 abuts against the top surface of the second extension end 2022, so as to prevent the rocking arm 402 from rotating due to being inserted into the first groove 4011 during the movement of the rocking disc 20.
[0037] Furthermore, to avoid requiring a large number of rotations of the rod 401 to pull out the sliding plate 202 when bottle removal is needed, and to improve bottle removal efficiency, such as... Figure 5 As shown, the end of the rod 401 away from the second extension end 2022 has a material removal notch 4012. The material removal notch 4012 extends to one side of the slot 20231, and makes the highest point on one side of the slot 20231 lower than the highest point on the other side of the slot 20231.
[0038] It should be noted that, due to the material removal notch 4012, when the rod 401 separates from the bottom wall of the slot 20231, the rod 401 will be directly opposite the material removal notch 4012 within a few turns. At this time, when the sliding plate 202 is pulled out, the rod 401 will not interfere with the movement of the guide part 2023.
[0039] Furthermore, in order to ensure that the second semi-conical fastener 2021 can abut against the first semi-conical fastener 2011, such as... Figure 5 As shown, the slot 20231 has an inclined surface 20232 on the side near the material removal notch 4012, and the rod 401 abuts against or separates from the inclined surface 20232.
[0040] Furthermore, to guide the sliding plate 202, such as... Figure 3As shown, the sliding plate 202 on one of the stepped surfaces 201 has a plurality of guide grooves 2024 on the side near the adjacent step surface 201, and a plurality of guide rods 2014 are vertically arranged on the step surface 201 adjacent to the guide grooves 2024, and the guide rods 2014 are slidably disposed in the guide grooves 2024.
[0041] In addition, such as Figure 3 As shown, a threaded fastener 20221 is provided at one end of the guide portion 2023 on the sliding plate 202 with the material removal notch 4012. When the sliding plate 202 slides a predetermined distance, the threaded fastener 20221 abuts against the horizontal section 20131.
[0042] It should be noted that the sliding plate 202 on the higher step surface 201 is provided with the guide groove 2024. After the sliding plate 202 is pulled out a predetermined distance, the guide rod 2014 abuts against the guide groove 2024 to prevent the guide part 2023 from separating from the horizontal section 20131. However, since there is no lower step surface 201 below the sliding plate 202, the threaded fastener 20221 is provided on the sliding plate 202 to prevent the guide part 2023 from separating from the horizontal section 20131 after the sliding plate 202 is pulled out a predetermined distance.
[0043] In summary, the bottle disassembly and assembly structure for the shaker described in the embodiments of this application is explained, which provides advantages such as simultaneous opening or fastening of multiple second semi-conical fasteners and higher bottle disassembly and assembly efficiency.
[0044] It is worth mentioning that, in this embodiment, the bottle-disassembly structure for the shaker is simple in structure, does not involve complex manufacturing processes or expensive materials, and is highly economical. At the same time, for manufacturers, the bottle-disassembly structure for the shaker provided in this application is easy to produce and inexpensive, which is more conducive to controlling production costs and further facilitates product promotion and use.
[0045] Those skilled in the art should understand that the embodiments of the present invention described above and shown in the accompanying drawings are merely examples and do not limit the present invention. The purpose of the present invention has been fully and effectively achieved. The function and structural principle of the present invention have been shown and explained in the embodiments, and any modifications or variations may be made to the implementation of the present invention without departing from these principles.
Claims
1. A bottle assembly / disassembly structure for a bottle shaker, comprising a housing, characterized in that: The bottle disassembly and assembly structure for the shaker includes A rocking disc, horizontally movably mounted on the housing, the rocking disc having multiple stepped surfaces, each stepped surface having multiple spaced-apart first semi-conical fasteners, and each stepped surface having a sliding plate slidably disposed thereon, the sliding plate having multiple spaced-apart second semi-conical fasteners, the first semi-conical fasteners and the second semi-conical fasteners being arranged opposite to each other, and when the sliding plate slides, the second semi-conical fasteners abut against or separate from the first semi-conical fasteners; and Several locking devices for fixing the relative position of the sliding plate and the corresponding step surface.
2. The bottle assembly / disassembly structure for a bottle shaker according to claim 1, characterized in that: Each of the stepped surfaces has a first extension end at both ends, the first extension end including a horizontal section and a vertical section. Each of the sliding plates has a second extension end at both ends, each of the second extension ends having a guide portion. The guide portion is slidably disposed on the horizontal section and has a slot. Each of the locking devices includes a rod, the rod being threadedly connected to the vertical section. When the rod rotates a predetermined angle, the rod engages or disengages from the slot.
3. The bottle assembly / disassembly structure for a bottle shaker according to claim 2, characterized in that: Each of the locking devices further includes a plug arm, the end of the rod opposite to the guide portion having a first groove, the top surface of the second extension end having a second groove, and the two ends of the plug arm having an insertion portion and a gripping portion respectively, the insertion portion being inserted into the first groove or the second groove.
4. The bottle assembly / disassembly structure for a shaker according to claim 3, characterized in that: The end of the rod opposite to the second extension end has a material removal notch, which extends to one side of the slot and makes the highest point on one side of the slot lower than the highest point on the other side of the slot.
5. The bottle assembly / disassembly structure for a bottle shaker according to claim 4, characterized in that: The slot has an inclined surface on the side near the material removal notch, and the rod abuts against or separates from the inclined surface.
6. The bottle assembly / disassembly structure for a shaker according to claim 4 or 5, characterized in that: The sliding plate on one of the steps has a plurality of guide grooves on the side near the adjacent step surface, and a plurality of guide rods are vertically arranged on the step surface adjacent to the guide grooves, the guide rods being slidably disposed in the guide grooves.
7. The bottle assembly / disassembly structure for a shaker according to claim 6, characterized in that: A threaded fastener is inserted through one end of the guide portion of the sliding plate having the material removal notch. When the sliding plate slides a predetermined distance, the threaded fastener abuts against the horizontal section.
8. The bottle assembly / disassembly structure for a bottle shaker according to claim 7, characterized in that: The housing also has a receiving cavity, and the bottle disassembly and assembly structure of the shaker also includes a motor and an eccentric component. The motor is placed in the receiving cavity, the motor shaft is fixedly connected to one end of the eccentric component, and the other end of the eccentric component is connected to the shaking disk.