Jumping platform of startle reflex system
By installing limiters and elastic connecting rods in the shock reflection test bench, the problem of sensor damage was solved, and the reliability and data accuracy of the test bench were improved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI YUYAN SCIENCE INSTRUMENT CO LTD
- Filing Date
- 2025-07-10
- Publication Date
- 2026-06-26
Smart Images

Figure CN224402583U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of modern biomedicine, and in particular to a shock reflex system platform. Background Technology
[0002] In modern biomedical experiments, the startle reflex experiment utilizes an experimental platform to investigate the animal's nervous system's response to stimuli. This platform integrates acoustic, optical, and electrical stimulation modules and is equipped with high-precision sensors to record the startle response of mice. However, existing technologies have drawbacks: the sensors have short measurement ranges and are easily damaged during transport due to bumps and collisions. Improper operation during use can also cause the sensors to be subjected to external forces exceeding their measurement range, leading to significant damage and increased experimental costs and time. Therefore, this invention aims to solve the problem of sensor damage due to external forces exceeding their measurement range, thereby improving the reliability and economy of the experimental platform. Utility Model Content
[0003] To address the shortcomings of existing shock reflection test platform technologies, such as the susceptibility of sensors to damage due to excessive external force and the interference of aftershocks from the platform with experimental data, this invention provides a shock reflection system platform. By setting a limiter and an elastic connecting rod between the platform and the pressure sensor, combined with a suspended installation structure with a through hole in the upper base, the problem of sensor overload damage caused by transportation bumps or improper operation is effectively solved. At the same time, the limiter restricts the vibration amplitude of the platform to reduce the interference of aftershocks on the sensor, thus solving the problems of increased experimental costs and affected data accuracy mentioned in the background technology.
[0004] This utility model provides the following technical solution: a shock reflex system platform, including a base, a pressure sensor, a limiter, a connecting rod, a platform, a control box, and a stimulation module;
[0005] The base is a hollow cuboid structure with an open top;
[0006] The pressure sensor has a block-shaped structure and is located inside the base. The pressure sensor is also elastic.
[0007] The limiter has a block-shaped structure, with one end of the limiter perpendicularly connected to one end of the pressure sensor.
[0008] The connecting rod has a preset length and is positioned on top of the pressure sensor;
[0009] The platform is a plate-shaped structure and is located on top of the connecting rod;
[0010] The control box is a cuboid structure with one end open, and the open end of the control box is vertically set at one end of the base.
[0011] The stimulation module is located on the control box.
[0012] In one embodiment of the utility model, the height of the limiter is greater than the height of the pressure sensor, and there is a preset distance between the top of the limiter and the bottom of the stage.
[0013] In one embodiment of the utility model, the base includes an upper base and a lower base;
[0014] The top of the upper base has a first through hole, and the pressure sensor moves the platform up and down through the first through hole via a connecting rod;
[0015] The top of the lower base is connected to the bottom of the upper base, and one end of the lower base is connected through to the bottom of the opening of the control box. The pressure sensor is located inside the lower base.
[0016] In one embodiment of the utility model, the connecting rod is arranged parallel to the limiter, the top of the connecting rod protrudes from the top of the upper base, and the protruding part has a preset length.
[0017] In one embodiment of the utility model, it also includes a front panel and a through-panel pagoda elbow. The front panel is connected to one end of the control box opening, and the bottom of the opposite end of the front panel connected to the control box is connected to one end of the upper base. The front panel has a second through hole and a third through hole. The diameter of the second through hole is larger than the diameter of the third through hole, and the third through hole is located at the bottom of the second hole.
[0018] The through-panel pagoda elbow is located at the top of the front panel.
[0019] In one embodiment of the utility model, a data interface and an air vent are provided on the left side of the control box, with the air vent located at the bottom of the data interface.
[0020] In one embodiment of the utility model, the stimulation module includes an air tube, a horn, and a light;
[0021] The air inlet of the air duct is connected to the air outlet of the control box;
[0022] The speaker is located at one end of the front panel, and the speaker can pass through the second through hole;
[0023] The light is positioned below the speaker and can pass through the third through hole.
[0024] In one embodiment of the utility model, the stimulation module further includes stimulation wires, and a wire fixing bracket is provided on the right side of the lower base and the upper base away from the control box. The wire fixing bracket is used to fix the stimulation wires.
[0025] In one embodiment of the utility model, a PCB circuit board is also included. The PCB circuit board is disposed inside the control box. The speaker is electrically connected to the PCB circuit board, the lamp is electrically connected to the PCB circuit board, the stimulation wire is electrically connected to the PCB circuit board, and the pressure sensor is electrically connected to the PCB circuit board.
[0026] In one embodiment of the utility model, the stage is made of aluminum alloy and ABS plastic.
[0027] The beneficial effects of this utility model are:
[0028] The shock reflex system's platform features a hollow cuboid structure with an open top, providing stable support, reducing weight for easy movement and installation, and facilitating the installation, maintenance, and connection of internal components. The pressure sensor's block-shaped elastic design ensures stable installation, reduces wobbling, buffers impacts, extends lifespan, and sensitively detects pressure changes. The limiter's block-shaped vertical connection structure stably limits the pressure sensor's displacement and protects it, ensuring stable and reliable system operation. The pre-set length of the connecting rod limits the stage height, accurately transmitting pressure signals. The stage's plate-like structure provides a large load-bearing area, reducing interference, improving experimental realism, and facilitating cleaning and disinfection. The control box's open cuboid vertical design facilitates processing, installation, and component maintenance, enhancing system integrity and ease of operation. The stimulation module, located in the control box, provides a stable output of stimulation signals, allowing for precise control and adjustment to ensure effective stimulation.
[0029] Other features and aspects of the present invention will become clear from the following detailed description of exemplary embodiments with reference to the accompanying drawings. Attached Figure Description
[0030] The accompanying drawings, which are included in and form part of this specification, illustrate exemplary embodiments, features, and aspects of the present invention together with the specification and serve to explain the principles of the present invention.
[0031] Figure 1 This diagram shows the main structural structure of the shock reflex system of this utility model according to an embodiment of the present invention.
[0032] Figure 2 This diagram shows the connection structure below the platform according to an embodiment of the present invention; Detailed Implementation
[0033] Various exemplary embodiments, features, and aspects of the present invention will now be described in detail with reference to the accompanying drawings. The same reference numerals in the drawings denote elements that have the same or similar functions. Although various aspects of the embodiments are shown in the drawings, they are not necessarily drawn to scale unless specifically indicated otherwise.
[0034] It should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", and "circumferential" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model or simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0035] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this utility model, "a plurality of" means two or more, unless otherwise explicitly specified.
[0036] The term “exemplary” as used herein means “serving as an example, embodiment, or illustration.” Any embodiment illustrated herein as “exemplary” is not necessarily to be construed as superior to or better than other embodiments.
[0037] Furthermore, to better illustrate this utility model, numerous specific details are provided in the following detailed embodiments. Those skilled in the art should understand that this utility model can be implemented even without certain specific details. In some instances, methods, means, components, and circuits well-known to those skilled in the art have not been described in detail, in order to highlight the main points of this utility model.
[0038] The shock reflection system of this invention is an experimental device with a stable structure and efficient data acquisition function. It is applied in the modern biomedical field to solve problems such as easy damage to sensors and interference from aftershocks of the platform, thereby improving experimental efficiency and data accuracy.
[0039] Specific references Figures 1-2 As a specific embodiment of the shock reflex system platform of this utility model, the shock reflex system platform includes: a shock reflex system platform, including a base 110, a pressure sensor 210, a limiter 220, a connecting rod 230, a stage 120, a control box 130, and a stimulation module 140. The shock reflex system platform is mainly composed of the base 110, pressure sensor 210, limiter 220, connecting rod 230, stage 120, control box 130, and stimulation module 140. These components cooperate with each other to form a complete system that can realize the shock reflex detection function. Each component plays a specific role and none can be missing.
[0040] The base 110 is a hollow cuboid structure with an open top. As the basic support component of the entire platform, the open top design facilitates the internal installation of core components such as the pressure sensor 210. The hollow cuboid shape ensures structural stability while reducing the use of materials and lightening the overall weight. It also provides ample space for the connection and layout between various components.
[0041] Furthermore, such as Figure 1 As shown, the hollow cuboid structure with an open top is the basic load-bearing component of the entire platform, providing space for the internal installation of pressure sensors 210 and other components. From the outside, its regular cuboid shape and open top facilitate the assembly and layout of subsequent components.
[0042] The pressure sensor 210 has a block structure and is located inside the base 110. The pressure sensor 210 is elastic, and its block structure allows it to be stably placed inside the base 110. Its elasticity allows it to sensitively sense pressure changes from above. When the experimental object on the stage 120 moves, the pressure is transmitted to the pressure sensor 210 through the connecting rod 230, which then converts the pressure signal into an electrical signal, providing raw data for subsequent detection and analysis.
[0043] Furthermore, such as Figure 2 As shown, the pressure sensor 210 is block-shaped and located inside the base 110. It is set in the hollow part of the base 110 and, by virtue of its own elasticity, can sense the pressure changes transmitted by the upper stage 120. It is the core component for realizing pressure detection.
[0044] The limiter 220 has a block structure. One end of the limiter 220 is perpendicularly connected to one end of the pressure sensor 210. The block structure gives the limiter 220 good stability and strength. The perpendicular connection allows it to accurately limit the range of motion of the pressure sensor 210, preventing the pressure sensor 210 from excessive displacement or deformation when subjected to excessive pressure, thereby protecting the pressure sensor 210.
[0045] Furthermore, such as Figure 2 As shown, the limiter 220 is block-shaped, with one end vertically connected to the pressure sensor 210. It should be inside the base 110 and work in conjunction with the pressure sensor 210. When the external force on the pressure sensor 210 exceeds the preset safety range, the limiter 220 will restrict the movement range of the platform 120 to prevent it from being damaged due to accidental pulling or overloading.
[0046] The connecting rod 230 has a preset length and is set on top of the pressure sensor 210. The preset length can be set according to experimental requirements to ensure that the stage 120 is at a suitable height. Its main function is to connect the pressure sensor 210 and the stage 120, and accurately transmit the pressure changes on the stage 120 to the pressure sensor 210 to achieve effective force transmission.
[0047] Furthermore, such as Figure 2 As shown, the connecting rod 230 has a preset length. One end is connected to the pressure sensor 210 inside the base 110, and the other end supports the platform 120. It plays the role of force transmission and structural connection, so that the pressure sensor 210 can drive the platform 120 to move up and down through it, thereby realizing pressure sensing and feedback.
[0048] The stage 120 is a plate-shaped structure. The stage 120 is set on top of the connecting rod 230. The plate-shaped structure provides a large planar space for placing the experimental object, allowing the experimental object to move stably on it. Its position on top of the connecting rod 230 forms a certain distance from the base 110 and other components, reducing the interference of other components on the experimental object and ensuring that the experiment is carried out in a relatively independent environment.
[0049] Further such as Figure 1 and Figure 2 As shown, the stage 120 is a plate-shaped structure, located on top of the connecting rod 230, used to place experimental objects and provide an operating surface for the experiment. Its plate-shaped shape ensures the stability of placement and the convenience of operation.
[0050] The control box 130 is a cuboid structure with one open end. The open end of the control box 130 is vertically mounted on one end of the base 110. The cuboid structure facilitates processing and manufacturing as well as the installation and arrangement of internal components. The open end design makes it convenient to inspect and maintain the internal control components. The vertical mounting on one end of the base 110 enhances the connection stability between the control box 130 and the base 110, making it the installation carrier of the control hub of the entire system.
[0051] Furthermore, such as Figure 1 As shown, the control box 130 is a cuboid structure with one open end. The open end is vertically set at one end of the base 110. It is the mounting carrier of the system's control center and is used for control components such as integrated circuits and interfaces to realize the regulation of the stimulation module 140, etc.
[0052] The stimulation module 140 is mounted on the control box 130, which provides a stable mounting platform for the stimulation module 140, enabling it to work stably. The main function of the stimulation module 140 is to apply specific stimuli, such as sound, light, airflow, and electric shock, to the experimental subject on the stage 120 to induce a shock reflex in the experimental subject and provide triggering conditions for detection. The stimulation induced by the stimulation module 140 is a signal issued by a computer, which can be custom or a random event in the software's built-in algorithm.
[0053] Furthermore, such as Figure 1 As shown, the related components of the stimulation module 140 (such as the speaker 142, the lamp 143, the air duct 141, etc.) are set on the control box 130 and are used to apply stimulation to the experimental subject on the stage 120 to trigger the shock reflex. It is a key part to realize the experimental stimulation function.
[0054] In this embodiment, the height of the limiter 220 is greater than the height of the pressure sensor 210, and there is a preset distance between the top of the limiter 220 and the bottom of the platform 120. After the limiter 220 is vertically connected to the pressure sensor 210, because it is taller, when the platform 120 is subjected to downward pressure and the connecting rod 230 moves down, the limiter 220 will contact the bottom of the platform 120 before the pressure sensor 210. The existence of the preset distance provides space for the normal small movement of the platform 120, which does not affect the pressure sensor 210's perception of normal pressure changes, and can also stop the platform 120 from moving down in time when the pressure is too high, thus avoiding the pressure sensor 210 from being subjected to overload pressure.
[0055] In this embodiment, the base 110 includes an upper base 112 and a lower base 111. The top of the upper base 112 has a first through hole. The pressure sensor 210 drives the platform 120 to move up and down through the first through hole via a connecting rod 230. The top of the lower base 111 is connected to the bottom of the upper base 112. One end of the lower base 111 is connected to the bottom of the opening of the control box 130. The pressure sensor 210 is located inside the lower base 111. The lower base 111 serves as the main load-bearing structure, and the pressure sensor 210 is installed inside it. The upper base 112 and the lower base 111 are fixedly connected to form a complete base 110. The connecting rod 230 extends from the top of the pressure sensor 210, passes through the first through hole of the upper base 112, and is connected to the platform 120. When the pressure sensor 210 is subjected to pressure and undergoes elastic deformation, the platform 120 can be driven to move up and down above the upper base 112 via the connecting rod 230. The through connection between the lower base 111 and the control box 130 facilitates the interconnection of internal wiring or pipelines between the two.
[0056] In this embodiment, the connecting rod 230 and the limiter 220 are arranged parallel to each other. The top of the connecting rod 230 protrudes from the top of the upper base 112, and the protruding part has a preset length. The connecting rod 230 and the limiter 220 are kept parallel to each other to ensure that they do not interfere with each other during force or movement. The preset length of the top of the connecting rod 230 protruding from the top of the upper base 112 is just enough to make the stage 120 suspended at a suitable height, which ensures that there is enough space between the stage 120 and the upper base 112 for the experimental object to move, and also allows the pressure change to be accurately transmitted to the pressure sensor 210 below.
[0057] In this embodiment, a front panel 150 and a through-plate pagoda elbow 160 are also included. The front panel 150 is connected to one end of the opening of the control box 130. The bottom of the opposite end of the front panel 150 connected to the control box 130 is connected to one end of the upper base 112. The front panel 150 has a second through hole and a third through hole. The diameter of the second through hole is larger than the diameter of the third through hole. The third through hole is located at the bottom of the second hole. The through-plate pagoda elbow 160 is set on the top of the front panel 150. The front panel 150 closes the opening end of the control box 130 and connects to the upper base 112, which enhances the sealing and stability of the overall structure. The second through hole and the third through hole provide suitable installation positions for the subsequent installation of the horn 142 and the lamp 143, respectively. The through-plate pagoda elbow 160 is installed on the top of the front panel 150 and can be used to connect to an external gas pipe to realize the introduction or export of gas.
[0058] In this embodiment, a data interface 001 and an air duct are provided on the left side of the control box 130. The air duct is located at the bottom of the data interface 001. The data interface 001 is used to connect to an external data acquisition device or control terminal to realize data transmission and command interaction between the platform system and the external device. The air duct is located below it and can be connected to the air duct 141 to provide a gas source channel for the gas stimulation function in the stimulation module 140. This vertical layout makes reasonable use of the side space of the control box 130 and avoids mutual interference between the interfaces.
[0059] In this embodiment, the stimulation module 140 includes an air duct 141, a horn 142, and a lamp 143. The air inlet of the air duct 141 is connected to the air duct of the control box 130. The horn 142 is located at one end of the front panel 150 and can pass through a second through hole. The lamp 143 is located below the horn 142 and can pass through a third through hole. The air duct 141 connects to the air duct of the control box 130 through its air inlet to introduce and guide external gas to the vicinity of the stage 120 to form airflow stimulation. The horn 142 is installed at the corresponding position on the front panel 150, and its main body passes through the second through hole to ensure that the sound can be effectively transmitted to the area of the stage 120. The lamp 143 is installed below the horn 142 and passes through the third through hole to provide light stimulation to the stage 120. The three stimulation methods work together and can be used individually or in combination according to experimental needs.
[0060] In this embodiment, the stimulation module 140 also includes stimulation wires. A wire fixing bracket 170 is provided on the right side of the lower base 111 and the upper base 112 away from the control box 130. The wire fixing bracket 170 is used to fix the stimulation wires. One end of the stimulation wire is connected to the control element inside the control box 130, and the other end can extend to the vicinity of the stage 120 for applying electrical stimulation, etc. The wire fixing bracket 170 is installed on the right side of the base 110 to fix the stimulation wires in an orderly manner, so as to avoid the stimulation wires increasing the pressure on the stage 120 and ensure that the wires do not hinder the change of pressure.
[0061] In this embodiment, a PCB circuit board is also included. The PCB circuit board is located inside the control box 130. The speaker 142 is electrically connected to the PCB circuit board, the lamp 143 is electrically connected to the PCB circuit board, the stimulation wire is electrically connected to the PCB circuit board, and the pressure sensor 210 is electrically connected to the PCB circuit board. The PCB circuit board, as the core control component, is installed inside the control box 130 and is electrically connected to the speaker 142, the lamp 143, the stimulation wire, and the pressure sensor 210 through wiring, thereby enabling unified control of each component. It receives the electrical signal from the pressure sensor 210 and controls the speaker 142 to emit sound, the lamp 143 to emit light, and the stimulation wire to output stimulation signals according to a preset program, thereby realizing the automated operation of the system.
[0062] In this embodiment, the platform 120 is made of aluminum alloy and ABS (Acrylonitrile Butadiene Styrene) plastic. The platform 120 uses aluminum alloy as the base frame to ensure its structural strength and load-bearing capacity. ABS (Acrylonitrile Butadiene Styrene) plastic is used on the frame surface or non-load-bearing parts to change the vibration characteristics and reduce the duration of aftershocks caused by the animal's startled jumping.
[0063] Furthermore, the shock reflex system's platform uses a non-conductive material as its surface covering, and also features a waterproof platform structure to prevent animal excrement from contacting the equipment's circuit components. The application of non-conductive materials and a waterproof platform structure effectively prevents animal excrement from contacting circuit components, reduces the risk of short circuits, ensures stable operation of the equipment, and improves the continuity and reliability of experiments.
[0064] Furthermore, during the experiment, the mice were first restrained inside a mouse cage, which was then fixed to the stage 120 with two bolts. Subsequently, the mice were stimulated by means of blowing air through the air tube 141, emitting sound through the horn 142, or emitting light through the lamp 143. When stimulated, the mice would react with fright or shock, kicking the mouse cage forcefully, causing the cage to vibrate momentarily and increase the downward pressure. This force was transmitted through the stage 120 and the connecting rod 230 to the pressure sensor 210. At the same time, the computer recorded the mode and time of the stimulus and the changes in the pressure sensor 210, and then carried out statistical analysis.
[0065] This invention relates to a shock reflex system platform, which, through an optimized limiting structure, a split base design, a multi-dimensional stimulation module configuration, and stable circuit connections, achieves precise detection of shock reflexes in experimental subjects, improves system stability and ease of operation, and enhances experimental controllability and result reliability. Specifically, the limiting device is a block structure with one end perpendicularly connected to the other end of the pressure sensor. Its height is greater than that of the pressure sensor, and a preset distance is maintained between its top and the bottom of the stage. When the stage experiences downward pressure due to the movement of the experimental subject or other external forces, the limiter contacts the bottom of the stage before the pressure sensor, effectively limiting excessive downward movement of the stage and preventing the pressure sensor from being subjected to pressure exceeding its tolerance range. This provides robust protection for the pressure sensor, preventing damage due to overload and significantly extending its service life. The separate design of the upper and lower bases, combined with the first through hole, allows the pressure sensor to move the stage more smoothly. The front panel and the through-plate pagoda elbow enhance the integrity and practicality of the overall structure. The layout of the data interface and air inlet facilitates data transmission and gas introduction. The multi-form stimulation module, composed of the air inlet tube, horn, lamp, and stimulation wires, can stimulate the experimental subject from different sensory dimensions. Combined with the centralized control of the PCB circuit board, it ensures precise and controllable stimulation. The wire fixing bracket prevents messy wires from affecting the experiment. The stage, made of aluminum alloy and acrylonitrile-butadiene-styrene copolymer plastic, reduces the duration of aftershocks after the animal's startled jumping, comprehensively improving the overall performance of the shock reflex system's jumping platform.
[0066] The various embodiments of the present invention have been described above. These descriptions are exemplary and not exhaustive, nor are they limited to the disclosed embodiments. Many modifications and variations will be apparent to those skilled in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen to best explain the principles, practical application, or improvement of the technology in the market, or to enable others skilled in the art to understand the embodiments disclosed herein.
Claims
1. A jump for a startle reflex system, characterized in that It includes a base, pressure sensor, limiter, connecting rod, stage, control box, and stimulation module; The base is a hollow cuboid structure with an open top; The pressure sensor has a block-shaped structure, is disposed inside the base, and is elastic. The limiter is a block structure, and one end of the limiter is perpendicularly connected to one end of the pressure sensor. The connecting rod has a preset length and is disposed on top of the pressure sensor; The platform is a plate-shaped structure and is located on top of the connecting rod; The control box is a cuboid structure with one end open, and the open end of the control box is vertically disposed at one end of the base. The stimulation module is mounted on the control box.
2. The drop system of a startle reflex system according to claim 1, characterized in that The height of the limiter is greater than the height of the pressure sensor, and there is a preset distance between the top of the limiter and the bottom of the platform.
3. The drop platform of a startle reflex system according to claim 2, wherein The base includes an upper base and a lower base; The top of the upper base has a first through hole, and the pressure sensor drives the platform to move up and down through the first through hole via the connecting rod; The top of the lower base is connected to the bottom of the upper base, one end of the lower base is connected through to the bottom of one end of the control box opening, and the pressure sensor is located inside the lower base.
4. The drop system of a startle reflex system according to claim 3, characterized in that The connecting rod is arranged parallel to the limiter, and the top of the connecting rod protrudes from the top of the upper base, with the protruding part having a preset length.
5. The drop system of a startle reflex system according to claim 4, characterized in that It also includes a front panel and a through-panel pagoda elbow. The front panel is connected to one end of the control box opening. The bottom of the opposite end of the front panel connected to the control box is connected to one end of the upper base. The front panel has a second through hole and a third through hole. The diameter of the second through hole is larger than the diameter of the third through hole. The third through hole is located at the bottom of the second hole. The through-panel pagoda elbow is located at the top of the front panel.
6. The drop system of a startle reflex system according to claim 5, wherein The control box has a data interface and an air vent on its left side, with the air vent located at the bottom of the data interface.
7. The jumping platform of the shock reflection system according to claim 6, characterized in that, The stimulation module includes an air tube, a horn, and a light; The air inlet of the air duct is connected to the air inlet of the control box; The speaker is disposed at one end of the front panel, and the speaker can pass through the second through hole; The lamp is positioned below the speaker and can pass through the third through hole.
8. The jumping platform of the shock reflection system according to claim 7, characterized in that, The stimulation module also includes stimulation leads. A lead fixing bracket is provided on the right side of the lower base and the upper base away from the control box. The lead fixing bracket is used to fix the stimulation leads.
9. The jumping platform of the shock reflection system according to claim 8, characterized in that, It also includes a PCB circuit board, which is located inside the control box. The speaker is electrically connected to the PCB circuit board, the lamp is electrically connected to the PCB circuit board, the stimulation wire is electrically connected to the PCB circuit board, and the pressure sensor is electrically connected to the PCB circuit board.
10. The jumping platform of the shock reflection system according to claim 1, characterized in that, The stage is made of aluminum alloy and ABS plastic.