Intelligent experiment stop bar
By integrating a touch screen and a multi-interface network communication module into the experimental barrier, the problems of poor interactivity and weak environmental adaptability of traditional barriers are solved, realizing intelligent experimental operation and equipment linkage, and adapting to complex laboratory environments.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-07-22
- Publication Date
- 2026-07-10
AI Technical Summary
Traditional experimental barriers have poor interactivity, limited functionality, and weak environmental adaptability, failing to meet the multi-parameter adjustment and network communication needs of intelligent laboratories.
It adopts a touch screen display, a multi-interface network communication module and a high-precision low-voltage output module, combined with carbon steel and epoxy resin materials, to achieve visual operation and multi-functional integration, and supports high environmental adaptability.
It improves the convenience and accuracy of experimental operations, provides a visual operation interface, and supports stable operation in multi-device linkage and complex environments.
Smart Images

Figure CN224480709U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of experimental equipment, and more specifically to intelligent experimental barriers. Background Technology
[0002] In junior and senior high school physics, chemistry, and biology labs, there's an increasing trend towards combining intelligent teaching with hands-on experiments. However, current applications often utilize experimental examination equipment, with functions primarily focused on simulating exam conditions and only offering supplementary intelligent teaching features. Virtual simulation labs, on the other hand, are typically used only for virtual simulation, failing to integrate intelligent experiments with actual experimental operations. Furthermore, even if the lab tables and chairs are not worn out, achieving overall intelligentization requires only simple modifications to the standard lab tables.
[0003] Furthermore, traditional laboratory barriers are mostly mechanical structures with limited functionality, serving only for physical isolation or basic positioning, lacking intelligent interactive capabilities. As experimental scenarios increasingly demand real-time data processing, ease of operation, and equipment connectivity, existing barriers exhibit the following shortcomings: 1. Insufficient interactivity: Lack of a visual operating interface; parameter adjustment relies on manual mechanical adjustments, resulting in low efficiency and a high risk of errors; 2. Limited functionality: Only supporting basic physical support, unable to integrate intelligent functions such as network communication and multi-device linkage; 3. Poor environmental adaptability: Insufficient corrosion resistance and flame retardancy of the materials, making it difficult to meet the needs of complex laboratory environments, such as fluctuating temperature and humidity and chemical corrosion; 4. Weak expandability: Low hardware configuration, unable to support software upgrades or external high-precision detection equipment. Therefore, there is an urgent need for a laboratory barrier that integrates intelligent interaction, multi-parameter adjustment, and network communication functions to improve the convenience and accuracy of experimental operations. Utility Model Content
[0004] This utility model provides an intelligent experimental barrier bar, which has the advantages of solving the problems of poor interactivity, single function and weak environmental adaptability of traditional barrier bars by integrating a touch screen display, a multi-interface network communication module and a high-precision low-voltage output module.
[0005] The intelligent experimental barrier includes an intelligent barrier with a panel fixed to its front side. Two low-voltage output modules are symmetrically arranged on the panel. Two sets of AC / DC low-voltage power output ports are located between the two low-voltage output modules on the panel. Power supply modules are provided at both ends of the panel. A data transmission interface is also provided on the surface of the panel. Multiple screw holes are provided on the bottom surface of the panel.
[0006] The low-voltage output module includes a low-voltage electrical display screen mounted on the panel and four low-voltage electrical adjustment modules, with the four low-voltage electrical adjustment modules located at the lower end of the low-voltage electrical display screen.
[0007] A touch screen is installed in the center of the panel.
[0008] The power supply module includes a track power supply mounted on the panel, and a movable power supply module that is slidably connected within and electrically connected to the track power supply.
[0009] Compared with the prior art, the beneficial effects of the present invention are as follows:
[0010] 1. Intelligent Interaction: Visual operation is achieved through an 11.6-inch touch screen, supporting real-time parameter display and adjustment, improving experimental efficiency;
[0011] 2. Multifunctional integration: It integrates low-voltage output, network communication RJ45 / Bluetooth / WiFi, and multiple interface expansion Type-C / USB functions to meet the linkage control and data transmission needs of experimental equipment;
[0012] 3. High environmental adaptability: The combination of carbon steel body + epoxy resin spraying + mirror panel has a flame retardant rating of ≥B1, making it suitable for complex laboratory environments;
[0013] 4. High-precision adjustment: The low-voltage output module supports 0.1V resolution adjustment and rated current of 3A, meeting the requirements of precision experiments for voltage / current accuracy. Attached Figure Description
[0014] The present invention will now be described in further detail with reference to the accompanying drawings and specific implementation methods.
[0015] Figure 1 This is a schematic diagram of the structure of an intelligent experimental barrier.
[0016] Figure 2 This is the front view of the intelligent experimental barrier.
[0017] Figure 3 This is a front view of the retaining strip;
[0018] Figure 4 This is a top view of the retaining strip;
[0019] Figure 5 This is a downward view of the barrier strip;
[0020] Figure 6 This is the rear view of the retaining strip;
[0021] Figure 7 This is the right view of the retaining strip;
[0022] Figure 8 This is the left view of the retaining bar;
[0023] Figure 9 This is a structural diagram showing the assembly of the baffle strip with the table body.
[0024] In the diagram: 1. Intelligent barrier bar; 2. Track power supply; 3. Portable power module; 4. AC / DC low-voltage output port; 5. Low-voltage display screen; 6. Low-voltage adjustment module; 7. Touch display screen; 8. USB interface; 9. Type-C interface; 10. Screw hole; 11. Panel; 12. Table body. Detailed Implementation
[0025] See Figures 1 to 3 The diagram shows an embodiment of the present invention that solves the problems of poor interactivity, limited functionality, and weak environmental adaptability of traditional baffles.
[0026] The intelligent experimental barrier includes an intelligent barrier 1, with a panel 11 glued to the front side of the intelligent barrier 1. Two low-voltage output modules are symmetrically arranged on the panel 11. Two sets of AC / DC low-voltage output ports 4 are provided on the panel 11 between the two low-voltage output modules, with four AC / DC low-voltage output ports 4 in each set. Power supply modules are provided at both ends of the panel 11. Data transmission interfaces are also provided on the surface of the panel 11.
[0027] The intelligent baffle 1 has a power cord on the back. It supports AC220V±10% and 50Hz input power to ensure stable operation of the device under various voltage fluctuations.
[0028] The device can operate normally in environments with temperatures ranging from -10℃ to +40℃, relative humidity <25℃, and altitude <4000M, adapting to various laboratory environments.
[0029] The bottom surface of the panel 11 is provided with multiple screw holes 10. The panel 11 can be installed on the table body 12 by adhesive bonding, or screws can be passed through the tabletop of the table body 12 and screwed into the screw holes 10 to fix the intelligent barrier strip 1 on the table body 12, ensuring the stability of the intelligent barrier strip 1 on the table body 12. The screw fixing method facilitates the overall installation and removal of the intelligent barrier strip 1.
[0030] An 11.6-inch touchscreen display 7 is mounted in the center of the panel 11. The display has a resolution of 1920*1080, supports multi-touch, and is convenient for dual-user viewing and operation. It is equipped with an 8-core CPU with a clock speed of 2.2GHz, and ≥8GB+128GB of expandable memory, providing powerful data processing capabilities. It supports one RJ45 interface, Bluetooth, and WiFi connectivity, facilitating network access for data transmission and remote control.
[0031] The touchscreen display 7 allows users to easily perform various settings and operations, improving experimental efficiency. During use, users can perform various settings and operations via the touchscreen display 7, such as adjusting the voltage and current values of the low-voltage output module and checking network connection status. Simultaneously, the touchscreen display 7 supports Bluetooth and WiFi connectivity, allowing users to remotely control the device via mobile phone or computer for intelligent management.
[0032] In summary, this application integrates functions such as a touch display screen, power supply module, data transmission interface, and low-voltage output module into one unit, reducing the number of laboratory equipment, improving space utilization, and solving the problems of poor interactivity, limited functionality, and weak environmental adaptability of traditional baffles.
[0033] The main body of the intelligent barrier strip 1 is made of carbon steel. The surface of the intelligent barrier strip 1 is coated with an epoxy resin layer.
[0034] The panel 11 is made of mirrored PC material. The flame retardant rating of panel 11 is no lower than B1. The use of a high flame retardant mirrored panel and a stable power supply module ensures safe use of the equipment in a laboratory environment.
[0035] See Figure 2 A schematic diagram of an embodiment of the low-voltage output module according to the present invention is shown.
[0036] The low-voltage output module includes a low-voltage electrical display screen 5 mounted on the panel 11 and four low-voltage electrical adjustment modules 6, with the four low-voltage electrical adjustment modules 6 located at the lower end of the low-voltage electrical display screen 5.
[0037] Each side of the display screen is equipped with a set of low-voltage output modules. The low-voltage display screen 5 is a dual-color LCD screen with a size of no less than 3 inches. It can display voltage and current values, with AC adjustment of 1.5-30V and DC adjustment of 1.5-30V. The adjustment resolution is 0.1V, and the rated current value is 3A, providing flexible power support for experiments.
[0038] See Figures 1 to 3 The diagram shows an embodiment of the power supply module according to the present invention.
[0039] The power supply module includes a track power supply 2 mounted on the panel 11, and a movable power supply module 3 that is slidably connected within and electrically connected to the track power supply 2; the track power supply 2 has a length ≥ 25 cm.
[0040] Each side of panel 11 is equipped with a power supply rail interface at least 25cm long. A soft rubber protective pad is glued and fixed at the interface. The movable power module 3 supports five-hole socket modules and USB power supply modules, ensuring the stability and safety of the power supply. The soft rubber protective pad connects to the experimental platform rails to prevent mechanical wear and provides a stable AC220V±10% power supply to the internal circuitry.
[0041] See Figure 3 The diagram shows an embodiment of the data transmission interface according to the present invention.
[0042] The data transmission interface includes a USB interface 8 located above the low-voltage display screen 5 on the right side; the data transmission interface also includes a Type-C interface 9 located above the AC / DC low-voltage output port 4 on the right side.
[0043] USB port 8 and Type-C port 9 facilitate the connection of peripheral devices and can be used to connect external USB flash drives to store experimental data.
Claims
1. An intelligent experimental barrier, characterized in that, The device includes an intelligent baffle (1), a panel (11) is fixed to the front side of the intelligent baffle (1), and two low-voltage output modules are symmetrically arranged on the panel (11); two sets of AC / DC low-voltage power output ports (4) are arranged between the two low-voltage output modules on the panel (11); power supply modules are arranged at both ends of the panel (11); a data transmission interface is also arranged on the surface of the panel (11); and multiple screw holes (10) are arranged on the bottom surface of the panel (11).
2. The intelligent experimental barrier according to claim 1, characterized in that, The low-voltage output module includes a low-voltage electrical display screen (5) and four low-voltage electrical adjustment modules (6) disposed on the panel (11). The four low-voltage electrical adjustment modules (6) are disposed at the lower end of the low-voltage electrical display screen (5).
3. The intelligent experimental barrier according to claim 1, characterized in that, A touch screen (7) is installed in the center of the panel (11).
4. The intelligent experimental barrier according to claim 1, characterized in that, The power supply module includes a track power supply (2) disposed on the panel (11) and a movable power supply module (3) slidably connected in the track power supply (2) and electrically connected to the track power supply (2).
5. The intelligent experimental barrier according to claim 4, characterized in that, The length of the track power supply (2) is ≥25cm.
6. The intelligent experimental barrier according to claim 1, characterized in that, The data transmission interface includes a USB interface (8) located above the low-voltage display screen (5) on the right side.
7. The intelligent experimental barrier according to claim 6, characterized in that, The data transmission interface includes a Type-C interface (9) located above the right side 4.
8. The intelligent experimental barrier according to claim 1, characterized in that, The panel (11) is made of mirrored PC material.
9. The intelligent experimental barrier according to claim 1, characterized in that, The main body of the intelligent guardrail (1) is made of carbon steel.
10. The intelligent experimental barrier according to claim 9, characterized in that, The surface of the intelligent baffle (1) is coated with an epoxy resin layer.