A sliding benchtop fixture for instruments in a dynamic laboratory
By designing a sliding platform fixing device in the dynamic laboratory, the problem of instrument instability during movement was solved, achieving stable fixation and convenient operation of the instrument, and ensuring the accuracy and smoothness of the experiment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHINESE PEOPLES LIBERATION ARMY NAVAL SPECIALTY MEDICAL CENT
- Filing Date
- 2025-04-29
- Publication Date
- 2026-06-05
AI Technical Summary
In dynamic laboratories, instruments and equipment are difficult to keep stable during movement, and are prone to displacement or vibration, which affects the accuracy and smooth progress of experimental operations.
A fixing device including a platform base and a sliding component is designed. The platform base is provided with a sliding groove, and the sliding component is used to fix small and large instruments. The horizontal movement and fixing of the instrument can be achieved through the cooperation of the sliding groove and the sliding component.
This improves the ease of operation of the instrument in dynamic laboratories, ensuring the smooth and accurate conduct of experiments.
Smart Images

Figure CN224321453U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of dynamic laboratory technology, and in particular to a sliding table fixing device for instruments in a dynamic laboratory. Background Technology
[0002] A dynamic laboratory, also known as a mobile laboratory, is an experimental platform that can be deployed, moved, or relocated at any time and possesses specific experimental testing, analysis, and research capabilities. It is widely used in fields such as environmental monitoring, medical testing, food safety, emergency response, and scientific research.
[0003] To monitor experimental data in a dynamic laboratory, a variety of instruments and equipment are typically required. However, during the movement of a dynamic laboratory, different instruments and equipment need to be used alternately, necessitating frequent relocation. At the same time, these instruments and equipment are often difficult to keep stable, prone to displacement or vibration, which not only affects normal operation but may also reduce the accuracy of experimental data, thus hindering the smooth progress of scientific experiments. Utility Model Content
[0004] This utility model addresses the problems and shortcomings of existing technologies by providing a sliding tabletop fixing device for instruments in a dynamic laboratory.
[0005] The present invention solves the above-mentioned technical problems through the following technical solution:
[0006] This utility model provides a sliding tabletop fixing device for instruments in a dynamic laboratory. It is characterized by comprising a tabletop base and multiple sets of sliding components. The tabletop base is fixed to the upper surface of the tabletop in the dynamic laboratory and is arranged along the length of the tabletop. Multiple parallel sliding grooves are formed on the tabletop base along the length direction. Each sliding groove is fitted with at least one set of sliding components, each set of sliding components being used to fix a small instrument. Adjacent sliding grooves are fitted with at least one set of sliding components, each set of sliding components being used to fix a large instrument.
[0007] To address the problems of existing technologies, this invention utilizes a sliding groove and sliding assembly design to horizontally move and secure small or large instruments in a dynamic laboratory to a designated position according to the operator's needs. This improves operational convenience and ensures the smooth and accurate completion of scientific experiments. Attached Figure Description
[0008] Figure 1 This is a schematic diagram of the pre-assembly structure of the sliding tabletop fixing device for instruments in a dynamic laboratory according to a preferred embodiment.
[0009] Figure 2This is a schematic diagram of the assembled sliding tabletop fixing device for instruments in a dynamic laboratory according to a preferred embodiment.
[0010] Figure 3 This is a schematic diagram of the slide and sliding assembly of the preferred embodiment.
[0011] Figure 4 This is a cross-sectional view of the sliding tabletop fixing device for instruments in a dynamic laboratory according to a preferred embodiment.
[0012] Figure 5 This is a schematic diagram of the installation of the sliding component in this preferred embodiment. Detailed Implementation
[0013] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.
[0014] like Figure 1-5 As shown, this embodiment provides a sliding tabletop fixing device for instruments in a dynamic laboratory, including a tabletop base 1 and multiple sets of sliding components 2. The tabletop base 1 is fixed on the upper surface of the tabletop 6 in the dynamic laboratory and is arranged along the length direction of the tabletop 6. Multiple parallel sliding grooves 3 are opened on the tabletop base 1 along the length direction. Each sliding groove 3 is an upward-opening groove. The top of the groove has flanges 31 extending inward at both ends, so that the whole is an upward-opening C-shaped groove 32.
[0015] Specifically, each set of sliding components 2 includes a first slider 21 and a second slider 22 that are positioned opposite each other.
[0016] Each slide groove 3 is equipped with at least one set of sliding components 2, each set of sliding components 2 being used to fix a small instrument 4. When the sliding component 2 is used to fix a small instrument 4, the first slider 21 and the second slider 22 are respectively slidably fitted on opposite sides of a C-shaped groove 32.
[0017] At least one set of sliding components 2 are slidably mounted on two adjacent sliding grooves 3. Each set of sliding components 2 is used to fix a large instrument 5. When the sliding component 2 is used to fix a large instrument 5, the first slider 21 is slidably mounted on one side of a C-shaped groove 32, and the second slider 22 is slidably mounted on the opposite side of the adjacent C-shaped groove 32.
[0018] The first slider 21 includes a first vertical slider 211 and a first horizontal support plate 212. The first vertical slider 211 is composed of a first C-shaped sliding part 2111 with an opening at the bottom facing the second slider 22 and a first vertical sliding part 2112 at the top. The first C-shaped sliding part 2111 slides against one side wall of the C-shaped groove 32. The first vertical sliding part 2112 is exposed outside the C-shaped groove 32. The top of the first vertical sliding part 2112 is fixed with a first horizontal support plate 212 away from the second slider 22.
[0019] The second slider 22 includes a second vertical slider 221 and a second horizontal support plate 222. The second vertical slider 221 is composed of a second C-shaped sliding part 2211 with an opening at the bottom facing the first slider 21 and a second vertical sliding part 2212 at the top. The second C-shaped sliding part 2211 is slidably engaged with the other side wall of the C-shaped groove 32. The second vertical sliding part 2212 is exposed in the C-shaped groove 32. The top of the second vertical sliding part 2212 is fixed with a second horizontal support plate 222 away from the first slider 21.
[0020] The first C-shaped sliding part 2111 and the first vertical sliding part 2112 are integrally formed, and the second C-shaped sliding part 2211 and the second vertical sliding part 2212 are integrally formed.
[0021] Each first horizontal support plate 212 and the corresponding second horizontal support plate 222 are provided with through holes 23 for fixing small instruments 4 or large instruments 5.
[0022] Each first horizontal support plate 212 or second horizontal support plate 222 has an extension fixing plate fixedly attached to its side, and each first horizontal support plate 212 or second horizontal support plate 222 is integrally formed with the extension fixing plate. In this embodiment, each first horizontal support plate 212 has an extension fixing plate fixedly attached to its side, and the extension fixing plate is provided with at least one locking fastener 24 for locking the sliding assembly 2 of its group.
[0023] Each locking fastener 24 includes a locking hole, a nut 241, and a screw 242. The locking hole is formed on the extension fixing plate. The nut 241 is fixed to the bottom of the extension fixing plate and is coaxially arranged with the locking hole. The screw 242 passes through the locking hole and the nut 241 and is screwed to the nut 241. When the bottom of the screw 242 abuts against the table base 1, the sliding assembly 2 of the corresponding group is locked to the table base 1. Of course, the nut 241 can also be fixed to the top of the extension fixing plate.
[0024] The process of using the sliding tabletop fixing device for instruments in the dynamic laboratory is as follows: First, the small instrument 4 or large instrument 5 is fixed to the sliding assembly 2 through the through hole 23 on the sliding assembly 2 and the through hole at the bottom of the small instrument 4 or large instrument 5. Then, the first slider 21 and the second slider 22 of the sliding assembly 2 to which the small instrument 4 belongs are respectively slidably fitted onto opposite sides of a C-shaped groove 32; the first slider 21 of the sliding assembly 2 to which the large instrument 5 belongs is slidably fitted onto one side of a C-shaped groove 32, and the second slider 22 of the sliding assembly 2 to which the large instrument 5 belongs is slidably fitted onto opposite sides of adjacent C-shaped grooves 32. At this time, the small instrument 4 or large instrument 5 can move horizontally on the sliding groove 3 of the tabletop base 1. The operator can move the small instrument 4 or large instrument 5 to the designated position as needed, and then fix the position of the small instrument 4 or large instrument 5 by tightening the screw 242 to carry out the experimental operation.
[0025] This utility model, through the design of the sliding groove 3 and the sliding component 2, can move small instruments 4 or large instruments 5 in the dynamic laboratory horizontally to a designated position and fix them according to the needs of the operator, thereby improving the convenience of operation and ensuring the smooth and accurate completion of scientific experiments.
[0026] While specific embodiments of this utility model have been described above, those skilled in the art should understand that these are merely illustrative examples, and the scope of protection of this utility model is defined by the appended claims. Those skilled in the art can make various changes or modifications to these embodiments without departing from the principles and essence of this utility model, but all such changes and modifications fall within the scope of protection of this utility model.
Claims
1. A sliding tabletop fixing device for instruments in a dynamic laboratory, characterized in that, It includes a table base and multiple sets of sliding components. The table base is fixed to the upper surface of the table in the dynamic laboratory and is arranged along the length of the table. Multiple parallel sliding grooves are opened on the table base along the length direction. Each sliding groove is equipped with at least one set of sliding components, and each set of sliding components is used to fix a small instrument. Adjacent sliding grooves are equipped with at least one set of sliding components, and each set of sliding components is used to fix a large instrument.
2. The sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 1, characterized in that, Each of the grooves is an upward-opening groove, and the top of the groove has flanges extending inward at both ends, making the whole groove an upward-opening C-shaped groove.
3. The sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 2, characterized in that, Each set of sliding components includes a first slider and a second slider arranged opposite to each other. The first slider includes a first vertical slider and a first horizontal support plate. The first vertical slider is composed of a first C-shaped sliding part with an opening at the bottom facing the second slider and a first vertical sliding part at the top. The first C-shaped sliding part is slidably engaged with one side wall of the C-shaped groove. The first vertical sliding part is exposed outside the C-shaped groove. The top of the first vertical sliding part is fixed with a first horizontal support plate away from the second slider. The second slider includes a second vertical slider and a second horizontal support plate. The second vertical slider is composed of a second C-shaped sliding part with an opening at the bottom facing the first slider and a second vertical sliding part at the top. The second C-shaped sliding part is slidably engaged with the other side wall of the C-shaped groove. The second vertical sliding part is exposed outside the C-shaped groove. The top of the second vertical sliding part is fixed with a second horizontal support plate away from the first slider.
4. The sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 3, characterized in that, When a set of sliding components is used to fix a small instrument, the first slider and the second slider are respectively slidably fitted on opposite sides of a C-shaped groove; When a set of sliding components is used to fix a large instrument, the first slider is slidably fitted on one side of a C-shaped groove, and the second slider is slidably fitted on the opposite side of an adjacent C-shaped groove.
5. The sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 3, characterized in that, The first C-shaped sliding part and the first vertical sliding part are integrally formed, and the second C-shaped sliding part and the second vertical sliding part are integrally formed.
6. The sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 3, characterized in that, Each of the first horizontal support plate and the corresponding second horizontal support plate is provided with through holes for fixing small or large instruments.
7. A sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 3, characterized in that, Each of the first or second horizontal support plates has an extension fixing plate fixedly extending from its side, and the extension fixing plate is provided with at least one locking fixing member for locking the sliding assembly of the group to which it belongs.
8. A sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 7, characterized in that, Each of the locking fasteners includes a locking hole, a nut, and a screw. The locking hole is formed on the extension fixing plate. The nut is fixed on the extension fixing plate and is coaxially arranged with the locking hole. The screw passes through the locking hole and the nut and is screwed to the nut. When the bottom of the screw abuts against the table base, the sliding assembly of the group to which it belongs is locked with the table base.
9. A sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 8, characterized in that, The nut is fixed to the bottom of the extension fixing plate.
10. A sliding tabletop fixing device for instruments in a dynamic laboratory as described in claim 7, characterized in that, Each of the first or second horizontal bearing plates is integrally formed with the extended fixed plate.