An experimental table capable of being assembled and combined
The modular design of the experimental platform solves the problem of adaptability to different experimental projects and operator heights, enabling flexible fixation and height adjustment of equipment, thereby improving experimental efficiency and space utilization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QINGDAO YANJIUDING LABORATORY ENGINEERING CO LTD
- Filing Date
- 2025-07-15
- Publication Date
- 2026-06-09
AI Technical Summary
The experimental platform is not adaptable enough to different experimental projects and the height differences of operators, and cannot flexibly adjust the fixing method and height, resulting in low experimental efficiency.
An modular experimental platform was designed, which uses a combination of sliders and clamps to flexibly fix the equipment; the height adjustment of the platform bottom block and cylinder driven by cylinder, combined with the reasonable storage of the storage cabinet, can meet diverse experimental needs.
It enables rapid fixing and retrieval of experimental equipment, highly flexible adjustment, improves experimental efficiency and space utilization, and adapts to the needs of different experimental projects and operators.
Smart Images

Figure CN224332203U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of assembleable experimental benches, and in particular to an assembleable and combinable experimental bench. Background Technology
[0002] Laboratory benches are essential platforms for conducting experiments and storing instruments in hospitals, schools, chemical plants, research institutes, and other enterprises and institutions. They are the core platform for laboratory personnel to carry out experimental operations and are widely used in various types of laboratories.
[0003] Experimental activities often exhibit diverse characteristics in teaching experiments, scientific research testing, and industrial production. Different experimental projects require experimental equipment of varying specifications and shapes, and the load-bearing and fixing requirements of the experimental platform also differ. Furthermore, the height of operators varies, and different experimental projects have different requirements for the height of the experimental platform. As experiments progress, it may be necessary to adjust the structure of the experimental platform according to the actual situation to adapt to new experimental needs. Moreover, the rapid fixing and retrieval of experimental equipment, as well as the rational utilization of experimental platform space, are all important factors in improving experimental efficiency. Utility Model Content
[0004] The purpose of this invention is to solve the problems in the background technology by proposing an assembly-and-combination experimental platform.
[0005] To achieve the above objectives, the present invention adopts the following technical solution:
[0006] An assembleable experimental table includes an experimental table body, a platform mounted on the top of the experimental table body, a rectangular groove in the center of the platform, a slide bar fixedly mounted on the outer surface of the center of the rectangular groove, two clamping blocks slidably connected to the slide bar, and slots corresponding to experimental instruments in the side walls of the two clamping blocks, and two rotating buckles provided on the platform.
[0007] Preferably, the bottom of the platform is provided with a locking block, and the two sides of the locking block are provided with multiple circular grooves. The two sides of the experimental platform body are provided with multiple circular openings. Multiple reset springs are fixedly connected to the two sides of the experimental platform body, and the ends of the multiple reset springs away from the experimental platform body are fixedly connected with bolts.
[0008] Preferably, the experimental platform body has a groove that matches the card block, a cylinder is fixedly installed in the center of the groove, a buffer pad is installed on the telescopic end of the cylinder, and the top of the buffer pad can contact the card block.
[0009] Preferably, the experimental platform body has a groove that matches the card block, a cylinder is fixedly installed in the center of the groove, a buffer pad is installed on the telescopic end of the cylinder, and the top of the buffer pad can contact the card block.
[0010] Preferably, the side wall of the experimental platform body is provided with a storage cabinet.
[0011] Preferably, the length of the bolt is equal to the sum of the lengths of the circular opening and the circular groove.
[0012] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0013] 1. This utility model, by setting a slider, a clamping block slidably connected to the slider, and a slot on the side wall of the clamping block, can adjust the fixing method according to the specifications and shape of the experimental equipment, meeting the fixing needs of various experimental equipment in different enterprises and institutions such as hospitals, schools, chemical plants, and research institutes; at the same time, by setting a clamping block at the bottom of the platform, a groove in the experimental table body, a circular groove, a circular opening, and bolts, the height of the platform can be flexibly adjusted to accommodate operators of different heights and the height requirements of different experimental projects, effectively addressing the diverse characteristics of experimental activities.
[0014] 2. This utility model can quickly fix experimental components by setting rotating buckles on the platform, which facilitates the rapid installation and retrieval of experimental equipment; by setting storage cabinets on the side wall of the experimental platform, experimental equipment can be stored in an orderly manner, avoiding clutter and improving the utilization rate of platform space; in addition, by setting cylinders and buffer pads, the height adjustment of the platform is more convenient and labor-saving, reducing adjustment time and improving the overall efficiency of experimental operation in many ways. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the left side of an experimental platform that can be assembled and combined according to this utility model.
[0016] Figure 2 This is a schematic diagram of the disassembled structure of an experimental platform that can be assembled and combined according to this utility model;
[0017] Figure 3 This is a cross-sectional view of the platform structure of an assembleable experimental table proposed in this utility model.
[0018] Figure 4 This is a cross-sectional structural diagram of the experimental platform body of an assembleable experimental platform proposed in this utility model.
[0019] In the diagram: 1 Platform, 2 Experimental table body, 3 Rectangular groove, 4 Slider, 5 Clamping block, 6 Slot, 7 Rotating buckle, 8 Clamping block, 9 Circular groove, 10 Groove, 11 Cylinder, 12 Buffer pad, 13 Circular opening, 14 Bolt, 15 Return spring, 16 Storage cabinet, 17 Base, 18 Anti-slip pad. Detailed Implementation
[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.
[0021] Reference Figure 1-4 An assembleable experimental platform includes an experimental platform body 2, a platform 1 mounted on the top of the experimental platform body 2, the platform 1 serving as the main load-bearing surface for experimental operations and providing a stable operating space for various experimental activities; a rectangular groove 3 is provided in the center of the platform 1, which provides a reasonable spatial layout basis for the installation of subsequent components; a slider 4 is fixedly mounted on the outer surface of the center of the rectangular groove 3, which provides a guide rail for the sliding of the clamping block 5, ensuring that the clamping block 5 can move smoothly;
[0022] Two clamping blocks 5 are slidably connected to the slider 4. The spacing between the two clamping blocks 5 can be adjusted by sliding them on the slider 4 to accommodate experimental instruments of different sizes. The side walls of the two clamping blocks 5 are provided with slots 6 corresponding to the experimental instruments. The slots 6 can clamp and fix the experimental instruments to prevent them from shaking or slipping during the experiment. Two rotating buckles 7 are provided on the platform 1. The rotating buckles 7 can assist in fixing the experimental components placed on the platform 1, further enhancing the stability of the experimental instruments.
[0023] The bottom of platform 1 is provided with a locking block 8, which cooperates with the groove 10 of the experimental table body 2 and is a key component for connecting platform 1 and experimental table body 2; multiple circular grooves 9 are provided on both sides of the locking block 8, which are adapted to bolts 14 and provide multiple height settings for fixing platform 1; multiple circular openings 13 are provided on both sides of the experimental table body 2, which provide channels for the bolts 14 to be inserted.
[0024] Multiple return springs 15 are fixedly connected to both sides of the experimental platform body 2. The return springs 15 have an elastic return function. When the height of the platform 1 needs to be adjusted, the bolts 14 are pulled to deform the return springs 15. After the adjustment is completed, the return springs 15 can drive the bolts 14 to automatically return and lock into the corresponding circular grooves 9. The ends of the multiple return springs 15 away from the experimental platform body 2 are fixedly connected to the bolts 14. The bolts 14 pass through the circular openings 13 and lock into the circular grooves 9, thereby fixing the platform 1 at the set height position.
[0025] The experimental platform body 2 has a groove 10 that matches the locking block 8. A cylinder 11 is fixedly installed in the center of the groove 10. The cylinder 11 serves as a power device, providing driving force for the lifting and lowering of the platform 1, making the height adjustment of the platform 1 more convenient and effortless. A buffer pad 12 is installed at the telescopic end of the cylinder 11. The buffer pad 12 has a buffering and shock absorption function. When the cylinder 11 drives the platform 1 to lift and lower, it can reduce the collision and impact between the locking block 8 and the telescopic end of the cylinder 11, protecting the components. The top of the buffer pad 12 can contact the locking block 8, and the driving force is transmitted through the contact with the locking block 8 to achieve the smooth lifting and lowering of the platform 1.
[0026] The bottom of the experimental platform body 2 is fixedly connected to a base 17. Multiple anti-slip pads 18 are installed on the bottom of the base 17. The anti-slip pads 18 can increase the friction between the base 17 and the ground, further enhancing the anti-slip performance of the experimental platform and preventing the experimental platform from sliding due to external forces. The side wall of the experimental platform body 2 is provided with a storage cabinet 16. The storage cabinet 16 can be used to store experimental instruments, reagents and other items, so that experimental supplies can be stored in an orderly manner, improving the cleanliness of the surrounding environment of the experimental platform, and making it convenient to access items during experiments. The length of the bolt 14 is equal to the sum of the lengths of the circular opening 13 and the circular groove 9. This size design ensures that after the bolt 14 passes through the circular opening 13, it has enough length to fit into the circular groove 9, ensuring the fixing effect of the bolt 14 on the platform 1, so that the platform 1 is stably placed at the set height position.
[0027] The detailed working process of this utility model is as follows:
[0028] Place the experimental platform body 2 in a suitable position, and insert the locking block 8 at the bottom of the platform 1 into the groove 10 of the experimental platform body 2, thus initially connecting the platform 1 and the experimental platform body 2. At this time, the return spring 15 is in its natural state, and the bolt 14 passes through the circular openings 13 on both sides of the experimental platform body 2 and is inserted into the circular grooves 9 on both sides of the locking block 8, thus initially fixing the platform 1 at a certain height.
[0029] According to the specifications and shape of the equipment required for the experiment, slide two clamping blocks 5 on the slider 4 of platform 1 and adjust the distance between them. When the distance is appropriate, place the experimental equipment into the slot 6 on the side wall of the clamping block 5. The slot 6 fits the shape of the equipment, achieving initial fixation of the equipment. Then, rotate the two rotating buckles 7 on platform 1 to fasten the relevant experimental components, further enhancing the stability of the equipment placement and preventing shaking or displacement during the experiment.
[0030] If the height of platform 1 needs to be adjusted to suit the operator's height or the requirements of the experiment, pull the bolt 14 at one end of the return spring 15 to stretch the return spring 15 and disengage the bolt 14 from the circular groove 9. Activate the cylinder 11 in the center of the groove 10. The telescopic end of the cylinder 11 moves the buffer pad 12 up and down, causing the buffer pad 12 to contact the locking block 8 and push the platform 1 to rise or fall. When platform 1 reaches the appropriate height, close the cylinder 11, loosen the bolt 14, and the return spring 15 returns to its elastic deformation, causing the bolt 14 to pass through the circular opening 13 and re-lock into the corresponding circular groove 9, thus fixing the height of platform 1.
[0031] After the experiment is completed, rotate the buckle 7 to loosen it, push the two clamps 5 in opposite directions, and remove the experimental apparatus from the slots 6 of the clamps 5. If you need to disassemble the platform 1, pull the bolt 14 again to disengage it from the circular groove 9, and then pull the clamp 8 at the bottom of the platform 1 out of the groove 10 of the experimental table body 2.
[0032] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.
Claims
1. An assembleable experimental platform, comprising an experimental platform body (2), characterized in that: The experimental platform body (2) is equipped with a platform (1) on its top. A rectangular groove (3) is provided in the center of the platform (1). A slide bar (4) is fixedly installed on the outer surface of the center of the rectangular groove (3). Two clamping blocks (5) are slidably connected on the slide bar (4). The side walls of the two clamping blocks (5) are provided with slots (6) corresponding to the experimental instruments. Two rotating buckles (7) are provided on the platform (1).
2. The modular experimental platform according to claim 1, characterized in that: The bottom of the platform (1) is provided with a locking block (8), and multiple circular grooves (9) are provided on both sides of the locking block (8). Multiple circular openings (13) are provided on both sides of the experimental table body (2). Multiple reset springs (15) are fixedly connected to both sides of the experimental table body (2), and bolts (14) are fixedly connected to the ends of the multiple reset springs (15) away from the experimental table body (2).
3. The modular experimental platform according to claim 2, characterized in that: The experimental platform body (2) has a groove (10) that matches the card block (8). A cylinder (11) is fixedly installed in the center of the groove (10). A buffer pad (12) is installed at the telescopic end of the cylinder (11). The top of the buffer pad (12) can contact the card block (8).
4. The modular experimental platform according to claim 3, characterized in that: The bottom of the experimental platform body (2) is fixedly connected to a base (17), and a number of anti-slip pads (18) are installed on the bottom of the base (17).
5. The modular experimental platform according to claim 4, characterized in that: The experimental platform body (2) is equipped with a storage cabinet (16) on its side wall.
6. The modular experimental platform according to claim 5, characterized in that: The length of the bolt (14) is equal to the sum of the lengths of the circular opening (13) and the circular groove (9).