Visualizing smart intestinal hydrotherapy device
By coordinating the control of the visual components, supplementary lighting components, and water flow adjustment components, the problem of visual field deviation caused by the fixed direction of the light source in the existing technology is solved, realizing precise treatment and convenient operation of the intestinal hydrotherapy device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- GUANGZHOU LIWANJIE TECH CO LTD
- Filing Date
- 2026-05-20
- Publication Date
- 2026-07-14
AI Technical Summary
In existing visual colonic hydrotherapy devices, the fixed direction of the lighting source makes it impossible to automatically track the area impacted by the water flow, resulting in a deviation between the camera's field of view and the point of action of the water flow. This makes it difficult for operators to adjust the water flow impact effect in real time and accurately in the dynamic intestinal environment, affecting the accuracy and convenience of treatment.
It employs a visual component, a supplementary lighting component, a water flow adjustment component, and a controller. The controller drives the water flow adjustment component to dynamically change the water outlet direction, and simultaneously controls the supplementary lighting component to adjust the light direction so that it always illuminates the area impacted by the water flow, thus achieving a unified approach to observation and treatment.
It significantly improves the accuracy and safety of interventional therapy under visual guidance, simplifies the operation process, and enhances the ease of operation.
Smart Images

Figure CN122376902A_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of medical and health care equipment technology, and specifically relates to a visual intelligent intestinal hydrotherapy device. Background Technology
[0002] Colonic hydrotherapy is a method of cleansing, treating, or maintaining health by infusing liquid into the intestines. With technological advancements, existing technologies include solutions that integrate miniature cameras into the infusion head for visualization of the procedure, aiding in observation of the intestinal tract. Specifically, current visualization solutions typically mount the camera fixedly at the front of the infusion head, equipped with a light source. While the water is being infused, the light is turned on, and the camera captures images of the intestinal tract, transmitting these images to an external display for the operator's observation. The water flow usually exits from a pre-designed outlet on the infusion head in a fixed or limitedly adjustable direction.
[0003] However, in existing visualization solutions, the lighting source is mostly fixed in direction, which cannot automatically track and illuminate the specific area being impacted by the water flow. There is often a deviation between the camera's field of view and the point of impact of the water flow, making it difficult for operators to judge the impact effect of the water flow in real time and accurately and make immediate adjustments in the dynamic and complex intestinal environment, thus affecting the realization of precision treatment under visualization guidance. Summary of the Invention
[0004] To address the problems in existing visualization solutions where lighting sources are mostly fixed in direction, making it impossible to automatically track and illuminate the specific area being impacted by the water flow, and where there is often a discrepancy between the camera's field of view and the point of impact of the water flow, making it difficult for operators to accurately judge the impact effect of the water flow in real time and make immediate adjustments in the dynamic and complex intestinal environment, thus affecting the realization of precise treatment under visualization guidance, this solution provides a visualization-guided intelligent intestinal hydrotherapy device.
[0005] The objective of this invention can be achieved through the following technical solutions: A visual intelligent intestinal hydrotherapy device includes: a hydrogen-rich water manufacturing device, a conduit, an infusion head, a visual component, a supplemental lighting component, a water flow regulating component, a controller, and a display. The conduit connects the hydrogen-rich water manufacturing device and the infusion head. The visual component and the supplemental lighting component are disposed at the front end of the infusion head. The visual component is used to acquire image information of the front side of the infusion head, and the supplemental lighting component is used to emit light towards the front side of the infusion head. The water flow regulating component is disposed on the infusion head and is used to adjust the water outlet direction of the infusion head. The controller is electrically connected to the visual component, the supplemental lighting component, the water flow regulating component, and the display.
[0006] In some embodiments, the inlet head is provided with a water outlet, the water outlet being connected to the conduit; the water flow regulating component includes: A support plate is provided radially across the outlet, with both ends fixed to the inlet head; The first baffle is rotatably connected to one side of the support plate; The second baffle is rotatably connected to the other side of the support plate; The water flow regulating component has a first limit position and a second limit position. In the first limit position, the support plate, the first baffle and the second baffle are coplanar, thereby blocking the water outlet. In the second limit position, the first baffle and the second baffle are inclined towards the outside of the water outlet, thereby forming guide spaces between the first baffle and the water outlet and between the second baffle and the water outlet, respectively.
[0007] In some embodiments, the vision component includes a miniature camera and a shield, the shield being disposed on the side of the support plate facing outward from the outlet, and the miniature camera being disposed within the enclosed space formed by the shield and the support plate.
[0008] In some embodiments, the supplementary lighting assembly includes at least one first supplementary light and at least one second supplementary light. The first supplementary light is disposed on the side surface facing outward from the water outlet, and the second supplementary light is disposed on the side surface of the second baffle facing outward from the water outlet. When the water flow regulating assembly is in the second extreme position, the optical axes of the first supplementary light and the second supplementary light are respectively directed toward the extension direction of the guide space formed between the first baffle and the water outlet, and between the second baffle and the water outlet.
[0009] In some embodiments, the supplementary lighting assembly includes at least one first supplementary light and at least one second supplementary light, both of which are rotatably disposed on the side surface of the support plate facing outward from the water outlet and are respectively disposed adjacent to the first baffle and the second baffle; wherein, when the water flow regulating assembly is in the second extreme position, the optical axes of the first supplementary light and the second supplementary light are respectively directed toward the extension direction of the guide space formed between the first baffle and the water outlet, and between the second baffle and the water outlet.
[0010] In some embodiments, the visualized intelligent colonic hydrotherapy device further includes a synchronous drive component connected to the supplemental lighting component and the water flow adjustment component, so that the illumination direction of the supplemental lighting component is oriented toward the extension direction of the guide space.
[0011] In some embodiments, the synchronous drive assembly includes a drive device, a first rotating shaft, a second rotating shaft, a first synchronous gear, and a second synchronous gear; the first rotating shaft passes through the first baffle and is rotatably connected to the support plate, and the second rotating shaft passes through the second baffle and is rotatably connected to the support plate; the first synchronous gear is coaxially connected to the first rotating shaft, and the second synchronous gear is coaxially connected to the second rotating shaft; the drive device is drively connected to the first synchronous gear and the second synchronous gear, and the drive device is electrically connected to the controller.
[0012] In some embodiments, a first sealing element is provided on the outer peripheral side of the first baffle, and a second sealing element is provided on the outer peripheral side of the second baffle; at the first extreme position, the first sealing element seals between the first baffle and the inlet head, and the second sealing element seals between the second baffle and the inlet head.
[0013] The beneficial effects of this invention are as follows: This invention provides a visual intelligent intestinal hydrotherapy device. By setting up a visual component, a supplementary lighting component, a water flow adjustment component, a controller, and a display, the visual component provides a real-time intracavitary view. The controller drives the water flow adjustment component to dynamically change the water outlet direction according to operation commands, and simultaneously controls the supplementary lighting component to adjust the illumination direction so that it always illuminates the water flow impact area. This solves the problems of inaccurate treatment, cumbersome operation, and reliance on experience caused by the isolation of observation, lighting, and treatment actions in the prior art and reliance on manual coordination. It significantly improves the accuracy, safety, and ease of operation of interventional treatment under visual guidance. Attached Figure Description
[0014] To facilitate understanding by those skilled in the art, the present invention will be further described below with reference to the accompanying drawings.
[0015] Figure 1 This is a schematic diagram of the overall structure of a visual intelligent intestinal hydrotherapy device according to the present invention; Figure 2 This is a schematic diagram of the infusion head structure of a visual intelligent intestinal hydrotherapy device according to the present invention; Figure 3 This is a cross-sectional view of the infusion head of a visual intelligent intestinal hydrotherapy device of the present invention when the water flow adjustment component is in the first extreme position; Figure 4 This is a cross-sectional view of the infusion head of a visual intelligent intestinal hydrotherapy device of the present invention when the water flow adjustment component is in the second extreme position.
[0016] Explanation of main symbols In the figure: 10, hydrogen-rich water manufacturing device; 20, conduit; 30, inlet head; 40, vision component; 50, supplementary lighting component; 60, water flow regulation component; 61, support plate; 62, first baffle; 63, second baffle; 70, controller; 80, display; 90, synchronous drive component. Detailed Implementation
[0017] To further illustrate the technical means and effects of the present invention in achieving its intended purpose, the following detailed description of the specific implementation methods, structures, features, and effects of the present invention, in conjunction with the accompanying drawings and preferred embodiments, is provided.
[0018] Colonic hydrotherapy is a method of cleansing, treating, or maintaining health by infusing liquid into the intestines. With technological advancements, existing technologies include solutions that integrate miniature cameras into the infusion head for visualization of the procedure, aiding in observation of the intestinal tract. Specifically, current visualization solutions typically mount the camera fixedly at the front of the infusion head, equipped with a light source. While the water is being infused, the light is turned on, and the camera captures images of the intestinal tract, transmitting these images to an external display for the operator's observation. The water flow usually exits from a pre-designed outlet on the infusion head in a fixed or limitedly adjustable direction.
[0019] However, in existing visualization solutions, the lighting source is mostly fixed in direction, which cannot automatically track and illuminate the specific area being impacted by the water flow. There is often a deviation between the camera's field of view and the point of impact of the water flow, making it difficult for operators to judge the impact effect of the water flow in real time and accurately and make immediate adjustments in the dynamic and complex intestinal environment, thus affecting the realization of precision treatment under visualization guidance.
[0020] This invention provides a visualized intelligent intestinal hydrotherapy device, aiming to solve the problems in existing visualization solutions. These solutions often rely on fixed-direction lighting sources, which cannot automatically track and illuminate the specific area being impacted by the water flow. Furthermore, discrepancies frequently exist between the camera's field of view and the point of water flow application, making it difficult for operators to accurately assess the water flow's impact effect and make immediate adjustments in the dynamic and complex intestinal environment. This hinders the achievement of precise treatment under visualization guidance. The technical solution of this invention will be described in detail below, based on its working principle.
[0021] Please see Figure 1-4This embodiment provides a visual intelligent intestinal hydrotherapy device, including: a hydrogen-rich water manufacturing device 10, a conduit 20, an infusion head 30, a vision component 40, a supplementary lighting component 50, a water flow regulating component 60, a controller 70, and a display 80. The conduit 20 connects the hydrogen-rich water manufacturing device 10 and the infusion head 30. The vision component 40 and the supplementary lighting component 50 are disposed at the front end of the infusion head 30. The vision component 40 is used to acquire image information of the front side of the infusion head 30, and the supplementary lighting component 50 is used to emit light to the front side of the infusion head 30. The water flow regulating component 60 is disposed on the infusion head 30 and is used to adjust the water outlet direction of the infusion head 30. The controller 70 is electrically connected to the vision component 40, the supplementary lighting component 50, the water flow regulating component 60, and the display 80.
[0022] For example, the hydrogen-rich water manufacturing device 10 is a device that dissolves hydrogen in purified water through electrolysis, physical hydrogen dissolution or other technologies to prepare hydrogen-rich water with a certain hydrogen concentration. Its outlet is connected to the conduit 20 through a pipeline to provide a treatment medium for the entire hydrotherapy process.
[0023] For example, the inlet head 30 is a tubular instrument for entering the intestine, which has a flow channel communicating with the catheter 20 inside and an outlet at the front end.
[0024] For example, the vision component 40 is used to acquire images or video signals in real time, including the condition of the intestinal wall in front of the outlet and the area impacted by the water flow, and transmits the image information to the controller 70 and the display 80 via cable or wireless means, providing the operator with intuitive visual feedback.
[0025] For example, the supplemental lighting component 50 is positioned at the front end of the infusion head 30 to provide illumination in the dark environment inside the intestine, ensuring that the visual component 40 can acquire images with sufficient brightness and clarity.
[0026] For example, the water flow regulating component 60 is integrated at the front end of the inlet head 30 and acts on the outlet. It can change the main jet direction of the hydrogen-rich water flow ejected from the outlet by changing its shape or position.
[0027] It is understood that this embodiment, by setting up a visual component 40, a supplementary lighting component 50, a water flow adjustment component 60, a controller 70, and a display 80, allows the supplementary lighting component 50 to illuminate the area in front during treatment. Simultaneously, the visual component 40 acquires high-definition images and displays them on the display 80. The operator judges the image and issues commands through the controller 70. The controller 70 then drives the water flow adjustment component 60 to dynamically adjust the actual impact direction of the water flow, precisely targeting the observed specific area, thus unifying the observation field of view with the treatment action in space. Simultaneously, the controller 70 can coordinate with the supplementary lighting component 50, ensuring its illumination direction follows the water flow adjustment direction, guaranteeing that the area being rinsed always receives optimal lighting.
[0028] In some embodiments, the inlet head 30 is provided with a water outlet, which is connected to the conduit 20; the water flow regulating component 60 includes: a support plate 61, which spans the radial direction of the water outlet and is fixed at both ends to the inlet head 30; a first baffle 62, which is rotatably connected to one side of the support plate 61; and a second baffle 63, which is rotatably connected to the other side of the support plate 61; wherein the water flow regulating component 60 has a first limit position and a second limit position; in the first limit position, the support plate 61, the first baffle 62 and the second baffle 63 are coplanar, thereby blocking the water outlet; in the second limit position, the first baffle 62 and the second baffle 63 are inclined toward the outside of the water outlet, thereby forming guide spaces between the first baffle 62 and the water outlet and between the second baffle 63 and the water outlet, respectively.
[0029] For example, the support plate 61 is a strip plate with a certain width and thickness, and its two ends are fixed to the inner wall of the inlet head 30 surrounding the outlet by welding, bolts or snap-fitting. For example, the support plate 61 spans the entire outlet radially, thereby structurally dividing the outlet into two regions radially, and serving as a common base and rotation fulcrum for the installation of the first baffle 62 and the second baffle 63.
[0030] For example, the first baffle 62 and the second baffle 63 are symmetrical plate-shaped structures that are rotatably connected to the left and right sides of the support plate 61, respectively.
[0031] For example, the first extreme position of the water flow regulating component 60 refers to the state where both the first baffle 62 and the second baffle 63 are rotated to the same plane as the support plate 61. At this time, the first baffle 62, the second baffle 63, and the support plate 61 completely cover and block the outlet, which can temporarily shut off the water flow or prevent the backflow of intestinal contents. For example, the second extreme position refers to the extreme state reached after the first baffle 62 and the second baffle 63 are rotated from their coplanar positions towards the direction outside the outlet by an angle. At this time, both the first baffle 62 and the second baffle 63 are in an inclined state, and a gradually widening wedge-shaped gap is formed between their side facing the outlet and the edge of the outlet, which is the guiding space. Among them, part of the water flow sprayed from the outlet is guided to one side by the inner side of the first baffle 62, and the other part is guided to the other side by the inner side of the second baffle 63, thereby separating the originally concentrated single stream of water and guiding it to two specific lateral angles, realizing the regulation of the water flow direction.
[0032] It is understood that the water flow regulating component 60 in this embodiment intervenes in the ejection direction of the water flow sprayed from the outlet through the first baffle 62 and the second baffle 63. Specifically, when the water flow regulating component 60 is in the second extreme position, the first baffle 62 and the second baffle 63 act as guide walls, and through interaction with the water flow, partially convert the momentum of the water flow into momentum tangentially along the guide walls, thereby forcibly changing the macroscopic motion direction of the water flow. The size and angle of the guide space are directly determined by the tilt angle of the first baffle 62 and the second baffle 63. Therefore, by controlling the rotation angle of the first baffle 62 and the second baffle 63, stepless or stepped adjustment of the water flow direction within a certain range can be achieved.
[0033] In some embodiments, the vision component 40 includes a miniature camera and a baffle, the baffle being disposed on the side of the support plate 61 facing outward from the outlet, and the miniature camera being disposed within the enclosed space formed by the baffle and the support plate 61.
[0034] For example, the baffle is a cover with a transparent observation window, which is sealed and fixed to the surface of the support plate 61 facing the outside of the outlet by means of snaps, threads, or adhesive. For example, the baffle is medical glass or resin lens.
[0035] For example, the miniature camera is fixed within the enclosed space formed by the cover and the support plate 61, with its lens facing the transparent observation window of the cover to ensure an unobstructed view.
[0036] In a first embodiment, the supplementary lighting component 50 includes at least one first supplementary light and at least one second supplementary light. The first supplementary light is disposed on the side surface facing outward from the water outlet, and the second supplementary light is disposed on the side surface of the second baffle 63 facing outward from the water outlet. When the water flow regulating component 60 is in the second extreme position, the optical axes of the first supplementary light and the second supplementary light are respectively directed toward the extension direction of the guide space formed between the first baffle 62 and the water outlet, and between the second baffle 63 and the water outlet.
[0037] For example, the first and second supplementary lights are miniature, high-brightness LED beads, which are directly embedded or bonded to the outer surface of their respective first baffle 62 and second baffle 63 through a water-resistant sealing process.
[0038] For example, since the first and second fill lights are fixedly connected to the rotatable baffle, the spatial orientation of the first and second fill lights is completely synchronized with the tilt angle of the baffle. When the drive mechanism drives the first baffle 62 and the second baffle 63 to rotate outward from the first extreme position of the coplanar plane to the second extreme position of the tilt, the fill lights fixed on the baffle also rotate synchronously by the same angle.
[0039] Understandably, the first and second supplementary lights, as auxiliary components of the first baffle 62 and the second baffle 63, have their illumination direction locked to always be perpendicular to the first baffle 62 and the second baffle 63. When the first baffle 62 and the second baffle 63 rotate to form a specific water flow guiding space, the optical axes of the first and second supplementary lights naturally and necessarily align with the area in front of the guiding space. This ensures that no matter which lateral angle the water flow is adjusted to, the first or second supplementary light that provides illumination for the water flow at that angle can immediately and automatically project its strongest light onto the path and target area that the water flow is about to impact.
[0040] In the second embodiment, the supplementary lighting component 50 includes at least one first supplementary light and at least one second supplementary light. The first and second supplementary lights are rotatably disposed on the side surface of the support plate 61 facing outward from the water outlet, and are respectively disposed adjacent to the first baffle 62 and the second baffle 63. When the water flow regulating component 60 is in the second extreme position, the optical axes of the first and second supplementary lights are respectively directed toward the extension direction of the guide space formed between the first baffle 62 and the water outlet, and between the second baffle 63 and the water outlet.
[0041] For example, the first supplementary light and the second supplementary light are each mounted on the outer surface of the support plate 61 via an independent miniature rotating seat, located on both sides of the support plate 61 and adjacent to the rotation root of the first baffle 62 and the second baffle 63, respectively. The miniature rotating seat integrates a miniature drive motor for driving the first supplementary light and the second supplementary light to rotate independently around the radial direction of the water outlet and the length direction of the support plate 61.
[0042] For example, when the controller 70 drives the water flow adjustment component 60 according to the operation command, causing the first baffle 62 and the second baffle 63 to rotate to the second limit position or the intermediate angle, the controller 70 synchronously calculates the theoretical extension direction of the corresponding guide space and generates a corresponding control signal to drive the adjacent first or second supplementary light to rotate, so that its optical axis is precisely aligned with the calculated direction.
[0043] It is understood that in this embodiment, the illumination direction control of the first and second supplementary lights is decoupled from the flow guidance direction control of the first baffle 62 and the second baffle 63. The two are softly coordinated through the programming logic of the controller 70, so that the illumination direction is no longer strictly limited by the physical angle of the first baffle 62 and the second baffle 63, but can be finely adjusted according to the optical optimization principle. For example, the optical axes of the first and second supplementary lights can be controlled to slightly lead the water flow guide line to pre-illuminate the area further ahead; or the angles of the first and second supplementary lights can be dynamically finely adjusted according to the image brightness fed back by the vision component 40 to eliminate shadows or reflections.
[0044] In some embodiments, the visual intelligent colonic hydrotherapy device further includes a synchronous drive component 90, which is connected to the supplementary lighting component 50 and the water flow adjustment component 60 so that the illumination direction of the supplementary lighting component 50 is oriented toward the extension direction of the guide space.
[0045] For example, a first rotating shaft passes through the first baffle 62 and is rotatably connected to one side of the support plate 61, serving as the power shaft driving the first baffle 62 to rotate. A second rotating shaft passes through the second baffle 63 and is rotatably connected to the other side of the support plate 61, serving as the power shaft driving the second baffle 63 to rotate. A first synchronous gear is coaxially and fixedly connected to the first rotating shaft, and a second synchronous gear is coaxially and fixedly connected to the second rotating shaft. The drive motor meshes with the first and second synchronous gears through a synchronous gear belt mechanism. When the drive motor operates, its torque is transmitted simultaneously, equally, but in opposite directions to the first and second rotating shafts through the gear pairs, thereby driving the first baffle 62 and the second baffle 63 to rotate synchronously in opposite directions.
[0046] In some embodiments, the synchronous drive assembly 90 includes a drive device, a first rotating shaft, a second rotating shaft, a first synchronous gear, and a second synchronous gear; the first rotating shaft passes through a first baffle 62 and is rotatably connected to a support plate 61, and the second rotating shaft passes through a second baffle 63 and is rotatably connected to the support plate 61; the first synchronous gear is coaxially connected to the first rotating shaft, and the second synchronous gear is coaxially connected to the second rotating shaft; the drive device is drively connected to the first synchronous gear and the second synchronous gear, and the drive device is electrically connected to the controller 70.
[0047] For example, the drive device is typically a miniature bidirectional stepper motor or servo motor, which is fixed in a suitable position inside the support plate 61 or the guide head 30 by a motor mounting bracket; the first synchronous gear and the second synchronous gear are a pair of gears with the same module and number of teeth. When the controller 70 issues a rotation command to the drive motor, the torque of the motor drives the first shaft and the second shaft to rotate at the same angular velocity in opposite directions.
[0048] In some embodiments, a first sealing element is provided on the outer periphery of the first baffle 62, and a second sealing element is provided on the outer periphery of the second baffle 63; at a first extreme position, the first sealing element is sealed between the first baffle 62 and the inlet head 30, and the second sealing element is sealed between the second baffle 63 and the inlet head 30.
[0049] For example, the first and second seals are typically annular or strip-shaped flexible sealing rings, such as those made of silicone or medical rubber, and are respectively installed in specially opened mounting grooves on the outer peripheral edges of the first baffle 62 and the second baffle 63 by interference fit or adhesive bonding.
[0050] For example, when the water flow regulating assembly 60, driven by the driving device, rotates the first baffle 62 and the second baffle 63 to a state coplanar with the support plate 61, the first baffle 62, the second baffle 63, and the first and second seals thereon together form a complete sealing surface. At this time, the first seal is tightly pressed between the outer periphery of the first baffle 62 and the inner wall of the inlet head 30, and the second seal is tightly pressed between the outer periphery of the second baffle 63 and the inner wall of the inlet head 30. Due to the elastic deformation of the first and second seals, they effectively fill all the assembly gaps between the first baffle 62, the second baffle 63, and the inner wall of the inlet head 30, respectively.
[0051] The above description is merely a preferred embodiment of the present invention and is not intended to limit the present invention in any way. Although the present invention has been disclosed above with reference to preferred embodiments, it is not intended to limit the present invention. Any person skilled in the art can make some modifications or alterations to the above-disclosed technical content to create equivalent embodiments without departing from the scope of the present invention. Any simple modifications, equivalent changes and alterations made to the above embodiments based on the technical essence of the present invention without departing from the scope of the present invention shall still fall within the scope of the present invention.
Claims
1. A visualized intelligent intestinal hydrotherapy device, characterized in that, include: The device comprises a hydrogen-rich water manufacturing apparatus, a conduit, an inlet head, a vision component, a supplementary lighting component, a water flow regulating component, a controller, and a display. The conduit connects the hydrogen-rich water manufacturing apparatus and the inlet head. The vision component and the supplementary lighting component are disposed at the front end of the inlet head. The vision component is used to acquire image information from the front side of the inlet head, and the supplementary lighting component is used to emit light towards the front side of the inlet head. The water flow regulating component is disposed at the inlet head and is used to adjust the water outlet direction of the inlet head. The controller is electrically connected to the vision component, the supplementary lighting component, the water flow regulating component, and the display.
2. The visualized intelligent intestinal hydrotherapy device according to claim 1, characterized in that, The inlet head is provided with a water outlet, which is connected to the conduit; the water flow regulating component includes: A support plate is provided radially across the outlet, with both ends fixed to the inlet head; The first baffle is rotatably connected to one side of the support plate; The second baffle is rotatably connected to the other side of the support plate; The water flow regulating component has a first limit position and a second limit position. In the first limit position, the support plate, the first baffle and the second baffle are coplanar, thereby blocking the water outlet. In the second limit position, the first baffle and the second baffle are inclined towards the outside of the water outlet, thereby forming guide spaces between the first baffle and the water outlet and between the second baffle and the water outlet, respectively.
3. The visualized intelligent intestinal hydrotherapy device according to claim 2, characterized in that, The vision component includes a miniature camera and a shield. The shield is disposed on the side of the support plate facing outward from the outlet, and the miniature camera is disposed in the enclosed space formed by the shield and the support plate.
4. The visualized intelligent intestinal hydrotherapy device according to claim 2, characterized in that, The supplementary lighting component includes at least one first supplementary light and at least one second supplementary light. The first supplementary light is disposed on the side surface facing outward from the water outlet, and the second supplementary light is disposed on the side surface of the second baffle facing outward from the water outlet. When the water flow regulating component is in the second extreme position, the optical axes of the first supplementary light and the second supplementary light are respectively directed towards the extension direction of the guide space formed between the first baffle and the water outlet, and between the second baffle and the water outlet.
5. The visualized intelligent intestinal hydrotherapy device according to claim 2, characterized in that, The supplementary lighting component includes at least one first supplementary light and at least one second supplementary light. The first and second supplementary lights are rotatably disposed on the side surface of the support plate facing outward from the water outlet, and are respectively disposed adjacent to the first and second baffles. When the water flow regulating component is in the second extreme position, the optical axes of the first and second supplementary lights are respectively directed toward the extension direction of the guide space formed between the first baffle and the water outlet, and between the second baffle and the water outlet.
6. The visualized intelligent intestinal hydrotherapy device according to claim 4 or 5, characterized in that, The visualized intelligent intestinal hydrotherapy device also includes a synchronous drive component, which is connected to the supplementary lighting component and the water flow adjustment component, so that the illumination direction of the supplementary lighting component is oriented towards the extension direction of the guide space.
7. The visualized intelligent intestinal hydrotherapy device according to claim 6, characterized in that, The synchronous drive assembly includes a drive device, a first rotating shaft, a second rotating shaft, a first synchronous gear, and a second synchronous gear; the first rotating shaft passes through the first baffle and is rotatably connected to the support plate, and the second rotating shaft passes through the second baffle and is rotatably connected to the support plate; the first synchronous gear is coaxially connected to the first rotating shaft, and the second synchronous gear is coaxially connected to the second rotating shaft; the drive device is drively connected to the first synchronous gear and the second synchronous gear, and the drive device is electrically connected to the controller.
8. The visualized intelligent intestinal hydrotherapy device according to claim 2, characterized in that, A first sealing element is provided on the outer periphery of the first baffle, and a second sealing element is provided on the outer periphery of the second baffle; at the first extreme position, the first sealing element seals between the first baffle and the inlet head, and the second sealing element seals between the second baffle and the inlet head.