A multi-channel volume cavity tube bank module

By designing a multi-channel volumetric tubular module that includes inlet, heating, and drainage components, the problems of fluid diversion, pressure relief, and metering in intraperitoneal treatment are solved, enabling precise control and stable injection and drainage of fluids, and improving the controllability of the treatment process.

CN224331298UActive Publication Date: 2026-06-09FUZHOU DONGZE MEDICAL DEVICES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
FUZHOU DONGZE MEDICAL DEVICES CO LTD
Filing Date
2025-06-08
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing abdominal treatment equipment lacks multi-channel volumetric tubing modules, which cannot achieve functions such as diversion, pressure relief, and metering, resulting in insufficient precision and stability in fluid injection and drainage.

Method used

Design a multi-channel volumetric tube module that includes inlet, heating and drain components. Utilize components such as a liquid transfer valve, heating control board, and flow sensor to achieve precise liquid diversion, pressure buffering, metering and heating functions.

Benefits of technology

It enables precise perfusion, rehydration, heating, and drainage of intraperitoneal fluid, ensuring the stability and safety of the fluid injection and drainage process, avoiding the influence of air on fluid pressure, and improving the controllability of the treatment process.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224331298U_ABST
    Figure CN224331298U_ABST
Patent Text Reader

Abstract

This utility model relates to the technical field of volumetric cavity tube assembly modules, and discloses a multi-channel volumetric cavity tube assembly module, including a frame. A partition is fixedly connected to the surface of the frame, and a replenishment tank is fixedly connected to the end face of the partition. A heating control board is fixedly connected to the inner wall of the partition near the replenishment tank, and a drain tank is fixedly connected to the surface of the partition near the frame. A top cover is fixedly connected to the surface of the frame away from the drain tank, and a sensor is snapped into the inner wall of the top cover. When in use, the liquid inlet component activates the liquid transfer valve, transferring the liquid from the two replenishment tanks through the liquid transfer pipe, ultimately to the combined liquid pipe, and finally to the outlet peristaltic pump. The outlet peristaltic pump activates, draining the liquid from the combined liquid pipe back into the inlet pipe, and then to the heating component. After completion in the heating component, the heating valve activates, and the heated liquid is transferred back to the combined liquid pipe through the heating pipe.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the technical field of volumetric cavity tube module equipment, specifically a multi-channel volumetric cavity tube module. Background Technology

[0002] Multichannel volumetric cavity tubing modules are structured modules that integrate fluid control, mixing, or transfer functions. They typically consist of multiple independent channels, cavities, and switching components, and are suitable for scenarios requiring precise fluid management.

[0003] Currently, some devices on the market use cartridges and tubing assemblies to divert fluid during abdominal treatment, but this only allows for through-flow without metering or pressure buffering. There are no multi-channel volumetric tubing modules that can provide diversion, pressure relief, and metering functions. This invention allows for controlled diversion, perfusion, resuscitation, heating, and drainage during abdominal treatment, achieving the goal of slowly injecting and draining fluid into the abdominal cavity while relieving pressure. Utility Model Content

[0004] The purpose of this invention is to provide a multi-channel volumetric cavity tube module to solve the problems mentioned in the background art.

[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:

[0006] This utility model relates to a multi-channel volumetric tubing module, comprising a frame, a partition fixedly connected to the surface of the frame, a replenishment tank fixedly connected to the end face of the partition, and a heating control plate fixedly connected to the inner wall of the partition near the replenishment tank. It also includes:

[0007] The liquid inlet component includes a liquid transmission valve, a liquid transmission tube is fixedly connected to the inner wall of the liquid transmission valve, and a liquid mixing tube is fixedly connected to the surface of the liquid transmission tube away from the liquid transmission valve.

[0008] A heating component, the heating component including a liquid replenishment valve, a liquid replenishment pipe fixedly connected to the inner wall of the liquid replenishment valve, and a heating box fixedly connected to the end face of the liquid replenishment pipe away from the liquid replenishment valve;

[0009] The drainage component includes a drainage tube, a drainage valve is fixedly connected to the end face of the drainage tube, and a drainage peristaltic pump is fixedly connected to the end face of the drainage valve near the end of the drainage tube.

[0010] Furthermore, a drain tank is fixedly connected to the surface of the partition near the vehicle frame, and a top cover is fixedly connected to the surface of the vehicle frame away from the drain tank. A sensor is snapped into the inner wall of the top cover. There are two partitions, which are equidistantly distributed along the surface of the vehicle frame. There are also two replenishment tanks, which are symmetrically distributed with respect to the surface of the partitions.

[0011] Furthermore, the liquid inlet component includes a liquid outlet peristaltic pump, the end face of which is fixedly connected to an inlet pipe, and two liquid transfer valves are provided, which are symmetrically distributed on the surface of the liquid transfer pipe. The end face of the liquid converging pipe away from the liquid transfer pipe is fixedly connected to the surface of the liquid outlet peristaltic pump.

[0012] Furthermore, an inlet valve is fixedly connected to the surface of the inlet pipe away from the outlet peristaltic pump. A balance volume chamber is fixedly connected to the end face of the inlet valve away from the inlet pipe. An outlet valve is fixedly connected to the surface of the balance volume chamber near the inlet valve. An outlet pipe is fixedly connected to the inner wall of the outlet valve. A bypass pipe is fixedly connected to the surface of the inlet pipe near the inlet valve. A bypass valve is fixedly connected to the end face of the bypass pipe away from the inlet valve. A heating valve is fixedly connected to the surface of the mixing pipe near the transmission pipe. A heating tube is fixedly connected to the surface of the heating valve away from the mixing pipe. There are two inlet valves, which are equidistantly distributed along the surface of the inlet pipe.

[0013] Furthermore, an infusion tube is fixedly connected to the end face of the outlet pipe away from the outlet valve, and a soft membrane conduit is fixedly connected to the end face of the infusion tube away from the outlet pipe. A horizontal axis plate is rotatably connected to the surface of the soft membrane conduit, and a thin film sleeve is provided on the surface of the soft membrane conduit away from the horizontal axis plate. There are two soft membrane conduits, which are symmetrically distributed around the surface of the horizontal axis plate. The surface of the horizontal axis plate is located inside the top cover. There are two thin film sleeves, which are symmetrically distributed along the surface of the top cover. The surface of the soft membrane conduit penetrates the surface of the thin film sleeve to the surface of the thin film sleeve away from the horizontal axis plate, and the surface of the thin film sleeve away from the horizontal axis plate is in contact with the surface of the sensor.

[0014] Furthermore, the heating component includes an output shaft, a stirring plate is fixedly connected to the surface of the output shaft, an output helical tooth plate is fixedly connected to the surface of the output shaft near the stirring plate, the end face of the replenishing valve away from the replenishing pipe is fixedly connected to the end face of the inlet pipe away from the outlet peristaltic pump, the surface of the heating box is disposed on the surface of the heating control plate, the number of stirring plates is set to six, the six stirring plates are divided into two groups, and the number of each group is set to three, the two groups of stirring plates are equidistantly distributed along the surface of the output shaft, and the surface of the heating pipe away from the heating valve is fixedly connected to the surface of the heating box.

[0015] Furthermore, a transmission helical tooth plate is meshed with the surface of the output helical tooth plate, a longitudinal stirring plate is fixedly connected to the surface of the transmission helical tooth plate away from the output helical tooth plate, and stirring teeth are fixedly connected to the end face of the transmission helical tooth plate away from the longitudinal stirring plate. There are two transmission helical tooth plates, which are symmetrically distributed with respect to the surface of the output helical tooth plate. The surface of the transmission helical tooth plate near the longitudinal stirring plate is rotatably connected to the inner wall of the heating box.

[0016] Furthermore, the drainage component includes a flow sensor, a pressure sensor is fixedly connected to the end face of the flow sensor, a bubble sensor is fixedly connected to the inner wall of the flow sensor on the side away from the pressure sensor, the end face of the drainage tube away from the drainage valve is fixedly connected to the surface of the bypass valve, the end face of the drainage valve away from the drainage tube is fixedly connected to the surface of the drainage tank, a soft membrane conduit is fixedly connected to the inner wall of the bubble sensor, the end face of the flow sensor away from the pressure sensor is fixedly connected to the surface of the sensor, and the surface of the soft membrane conduit away from the bubble sensor is in contact with the surface of the drainage peristaltic pump.

[0017] Furthermore, an inner slider is fixedly connected to the end face of the membrane sleeve away from the soft membrane conduit. A telescopic rod is fixedly connected to the surface of the inner slider. A positioning spring is fixedly connected to the surface of the inner slider away from the telescopic rod. There are two inner sliders, which are symmetrically distributed with respect to the surface of the telescopic rod. There are also two telescopic rods, which are symmetrically distributed with respect to the surface of the inner slider. There are two positioning springs, which are symmetrically distributed with respect to the surface of the inner slider. The surface of the inner slider is slidably connected to the inner wall of the frame. The end face of the positioning spring away from the inner slider is fixedly connected to the inner wall of the frame.

[0018] This utility model has the following beneficial effects:

[0019] When this invention is in use, the liquid transfer valve in the liquid inlet component is activated, transferring the liquid from the two replenishment tanks through the liquid transfer pipe, ultimately to the liquid combination pipe, and finally to the liquid outlet peristaltic pump. The liquid outlet peristaltic pump is activated, draining the liquid from the liquid combination pipe back into the liquid inlet pipe. Afterward, the liquid is transferred to the heating component. Once completed in the heating component, the heating valve is activated, and the heated liquid is transferred back to the liquid combination pipe through the heating pipe, finally flowing back into the liquid inlet pipe. Simultaneously, the bypass valve is activated, allowing the liquid in the liquid inlet pipe to exit through the bypass pipe, and expelling air from the device into the liquid outlet component. The air inside the device is completely expelled to prevent it from affecting the liquid pressure during use. Then, the inlet valve is activated and the bypass valve is closed, allowing the liquid in the inlet pipe to enter the balance volume chamber. Next, the outlet valve is activated, allowing the liquid to enter the outlet pipe, then through the outlet pipe to the infusion pipe, and finally to the diaphragm catheter. At the same time, the diaphragm catheter is passed through the membrane sleeve, with the membrane inside the membrane sleeve covering the surface of the diaphragm catheter, guiding the diaphragm catheter into the abdominal cavity for normal use, to infuse the fluid entering the abdominal cavity for rehydration.

[0020] When this invention is in use, when liquid from the inlet component enters the heating component, the replenishing valve is activated, transferring the liquid discharged from the inlet pipe through the replenishing pipe and ultimately into the heating chamber. Simultaneously, the heating control board is activated to heat the liquid entering the heating chamber and drives the output shaft. The output shaft then drives the stirring plate, which stirs the liquid entering the heating chamber, ensuring more complete and stable heating. Simultaneously, when the output shaft is running, it drives the output helical gear plate. Through surface meshing, the output helical gear plate drives the transmission helical gear plate to rotate along the inner wall of the heating chamber. When the transmission helical gear plate is running, it drives the longitudinal stirring plate, which guides the liquid in the heating chamber for better flow. Simultaneously, when the transmission helical gear plate is running, it drives the stirring teeth, which, together with the stirring plate, further stir the liquid in the heating chamber, ensuring more complete heating.

[0021] When this invention is in use, the soft membrane catheter inside the bubble sensor in the drainage component is transmitted to the abdominal cavity and connected to the soft membrane catheter in the inlet component. Then, the sensor controls the flow sensor, pressure sensor, and bubble sensor to start, monitoring the liquid in the soft membrane catheter. Simultaneously, when the bypass valve operates, it transmits the fluid to the drainage tube, venting air from the device into the drainage tank. Afterward, the drainage peristaltic pump and drainage valve start, controlling the outflow of liquid from the soft membrane catheter in the abdominal cavity. At the same time, the telescopic rod operates, controlling the inner sliders at both ends to slide along the inner wall of the frame. The two inner sliders control the movement of the membrane sleeve. The sensor monitors the soft membrane catheter within the membrane sleeve, controlling its inflow and outflow. Simultaneously, when the inner sliders move, they drive the positioning spring, which generates elastic force to assist in positioning and draining the liquid within the device, thus better assisting in the use of the device.

[0022] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0023] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0024] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0025] Figure 2 This is a cross-sectional view of the overall structure of this utility model;

[0026] Figure 3 This is a rear cross-sectional view of the liquid inlet component structure of this utility model;

[0027] Figure 4 This is a cross-sectional view of the liquid inlet component of this utility model;

[0028] Figure 5 This is a schematic diagram of the heating component structure of this utility model;

[0029] Figure 6 This is a cross-sectional view of the heating component structure of this utility model;

[0030] Figure 7 This is a rear cross-sectional view of the drainage component of this utility model;

[0031] Figure 8 This is a cross-sectional view of the drainage component of this utility model.

[0032] The attached diagram lists the components represented by each number as follows:

[0033] In the diagram: 1. Inlet component; 2. Heating component; 3. Drain component; 4. Frame; 5. Partition; 6. Replenishment tank; 7. Heating control board; 8. Drain tank; 9. Top cover; 10. Sensor; 11. Transfer valve; 12. Transfer pipe; 13. Combination pipe; 14. Peristaltic pump; 15. Inlet pipe; 16. Balance chamber; 17. Inlet valve; 18. Outlet valve; 19. Outlet pipe; 20. Bypass pipe; 21. Bypass valve; 22. Infusion pipe; 23. Soft membrane catheter; 24. Horizontal 25. Shaft plate; 26. Thin film sleeve; 27. Heating tube; 38. Heating valve; 39. Liquid replenishment valve; 30. Liquid replenishment pipe; 31. Heating box; 32. Output shaft; 33. Stirring plate; 34. Output helical tooth plate; 35. Transmission helical tooth plate; 36. Longitudinal stirring plate; 37. Stirring teeth; 48. Drainage pipe; 49. Drainage valve; 40. Drainage peristaltic pump; 41. Flow sensor; 42. Pressure sensor; 43. Bubble sensor; 44. Inner slider; 45. Telescopic rod; 46. Positioning spring. Detailed Implementation

[0034] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0035] Please see Figures 1-8 As shown, this utility model is a multi-channel volumetric tube assembly module, including a frame 4, a partition 5 fixedly connected to the surface of the frame 4, a replenishment tank 6 fixedly connected to the end face of the partition 5, and a heating control plate 7 fixedly connected to the inner wall of the partition 5 near the replenishment tank 6, and also including:

[0036] Liquid inlet component 1 includes a liquid transfer valve 11. When the liquid transfer valve 11 is activated, the liquid in the two replenishment tanks 6 is transferred out through the liquid transfer pipe 12 and finally transferred to the liquid collection pipe 13. The liquid transfer pipe 12 is fixedly connected to the inner wall of the liquid transfer valve 11, and the liquid collection pipe 13 is fixedly connected to the surface of the liquid transfer pipe 12 away from the liquid transfer valve 11. Finally, the liquid is transferred to the liquid outlet peristaltic pump 14 through the liquid collection pipe 13.

[0037] Heating component 2 includes a liquid replenishment valve 31. When liquid from liquid inlet component 1 enters heating component 2, liquid replenishment valve 31 is activated, and liquid discharged from liquid inlet pipe 15 is transmitted through liquid replenishment pipe 32 and finally transmitted to heating box 33. Liquid replenishment pipe 32 is fixedly connected to the inner wall of liquid replenishment valve 31, and heating box 33 is fixedly connected to the end face of liquid replenishment pipe 32 away from liquid replenishment valve 31.

[0038] The drainage component 3 includes a drainage tube 41. When the bypass valve 21 is running, the fluid is transmitted to the drainage tube 41, and then the air in the device is discharged into the drainage tank 8. After that, the drainage peristaltic pump 43 and the drainage valve 42 are started to control the discharge of the fluid in the soft membrane catheter 23 that has been transmitted to the abdominal cavity. The end face of the drainage tube 41 is fixedly connected to the drainage valve 42, and the end face of the drainage valve 42 near the end of the drainage tube 41 is fixedly connected to the drainage peristaltic pump 43.

[0039] A drain tank 8 is fixedly connected to the surface of the partition 5 near the side of the frame 4, and a top cover 9 is fixedly connected to the surface of the frame 4 away from the drain tank 8. A sensor 10 is snapped into the inner wall of the top cover 9. There are two partitions 5, which are equidistantly distributed along the surface of the frame 4. There are two replenishment tanks 6, which are symmetrically distributed with respect to the surface of the partition 5.

[0040] The liquid inlet component 1 includes a liquid outlet peristaltic pump 14. When the liquid outlet peristaltic pump 14 is started, it discharges the liquid transmitted to the liquid collection pipe 13 into the liquid inlet pipe 15. The liquid inlet pipe 15 is fixedly connected to the end face of the liquid outlet peristaltic pump 14. There are two liquid transmission valves 11, which are symmetrically distributed on the surface of the liquid transmission pipe 12. The end face of the liquid collection pipe 13 away from the liquid transmission pipe 12 is fixedly connected to the surface of the liquid outlet peristaltic pump 14.

[0041] An inlet valve 17 is fixedly connected to the surface of the inlet pipe 15 away from the outlet peristaltic pump 14. When the inlet valve 17 is activated, the bypass valve 21 is closed, and the liquid in the inlet pipe 15 is transferred into the balance volume chamber 16. The end face of the inlet valve 17 away from the inlet pipe 15 is fixedly connected to the balance volume chamber 16. An outlet valve 18 is fixedly connected to the surface of the balance volume chamber 16 near the inlet valve 17. When the outlet valve 18 is activated, the liquid is transferred into the outlet pipe 19. The outlet pipe 19 is fixedly connected to the inner wall of the outlet valve 18, and then the liquid is transferred to the infusion pipe 22 through the outlet pipe 19, and finally to the soft membrane conduit 23. A bypass pipe 20 is fixedly connected to the surface of the inlet pipe 15 near the inlet valve 17. The end face of the bypass pipe 20 away from the inlet valve 14 is fixedly connected to... A bypass valve 21 is connected. When the bypass valve 21 is activated, the liquid in the inlet pipe 15 is transmitted through the bypass pipe 20, and the air in the device is discharged into the drain component 3. All the air in the device is discharged to prevent the liquid pressure from being affected by the presence of air during use. A heating pipe 26 is fixedly connected to the surface of the liquid-binding pipe 13 near the liquid-transmitting pipe 12. The liquid is transmitted to the heating component 2. After it is completed in the heating component 2, the heating valve 27 is activated. The heated liquid is transmitted to the liquid-binding pipe 13 through the heating pipe 26, and finally to the inlet pipe 15. A heating valve 27 is fixedly connected to the surface of the heating valve 27 away from the liquid-binding pipe 13. There are two inlet valves 17, which are equidistantly distributed along the surface of the inlet pipe 15.

[0042] An infusion tube 22 is fixedly connected to the end face of the infusion tube 22 away from the infusion valve 18. A soft membrane catheter 23 is fixedly connected to the end face of the infusion tube 22 away from the infusion tube 19. The soft membrane catheter 23 is passed through a membrane sleeve 25, and the membrane inside the membrane sleeve 25 covers the surface of the soft membrane catheter 23, allowing the soft membrane catheter 23 to be introduced into the abdominal cavity for normal use, to infuse the fluid entering the abdominal cavity for rehydration. A transverse axis plate 24 is rotatably connected to the surface of the soft membrane catheter 23. The side of the soft membrane catheter 23 away from the transverse axis plate 24... The surface of the sensor 10 is provided with a thin film housing 25 and two soft film conduits 23. The two soft film conduits 23 are symmetrically distributed around the surface of the horizontal axis plate 24. The surface of the horizontal axis plate 24 is located inside the top cover 9. The two thin film housings 25 are symmetrically distributed along the surface of the top cover 9. The surface of the soft film conduit 23 penetrates the surface of the thin film housing 25 to the surface of the thin film housing 25 away from the horizontal axis plate 24. The surface of the thin film housing 25 away from the horizontal axis plate 24 is in contact with the surface of the sensor 10.

[0043] Heating component 2 includes an output shaft 34. When the heating control board 7 is activated, it heats the liquid entering the heating chamber 33 and simultaneously drives the output shaft 34. The output shaft 34 then drives the stirring plate 35. The stirring plate 35 is fixedly connected to the surface of the output shaft 34, and it stirs the liquid entering the heating chamber 33, ensuring more complete and stable heating. An output helical gear plate 36 is fixedly connected to the surface of the output shaft 34 near the stirring plate 35. When the output shaft 34 runs, it drives the output helical gear plate 36, which... Plate 36, through surface meshing, will drive the transmission helical gear plate 37 to rotate along the inner wall of the heating box 33. The end face of the replenishment valve 31 away from the replenishment pipe 32 is fixedly connected to the end face of the inlet pipe 15 away from the outlet peristaltic pump 14. The surface of the heating box 33 is set on the surface of the heating control plate 7. There are six stirring plates 35, which are divided into two groups, and each group has three stirring plates. The two groups of stirring plates 35 are equidistantly distributed along the surface of the output shaft 34. The surface of the heating pipe 26 away from the heating valve 27 is fixedly connected to the surface of the heating box 33.

[0044] The output helical toothed plate 36 is meshed with a transmission helical toothed plate 37. When the transmission helical toothed plate 37 runs, it drives the longitudinal stirring plate 38 to run. The longitudinal stirring plate 38 is fixedly connected to the surface of the transmission helical toothed plate 37 away from the output helical toothed plate 36. The longitudinal stirring plate 38 guides the liquid in the heating box 33 to run better. The end face of the transmission helical toothed plate 37 away from the longitudinal stirring plate 38 is fixedly connected with stirring teeth 39. When the transmission helical toothed plate 37 runs, it drives the stirring teeth 39 to run. The stirring teeth 39, together with the stirring plate 35, perform better stirring of the liquid in the heating box 33, making the liquid heat more completely. There are two transmission helical toothed plates 37. The two transmission helical toothed plates 37 are symmetrically distributed with respect to the surface of the output helical toothed plate 36. The surface of the transmission helical toothed plate 37 near the longitudinal stirring plate 38 is rotatably connected to the inner wall of the heating box 33.

[0045] The drainage component 3 includes a flow sensor 44. Sensor 10 controls the activation of the flow sensor 44, pressure sensor 45, and bubble sensor 46 to monitor the liquid in the soft membrane catheter 23. The end face of the flow sensor 44 is fixedly connected to the pressure sensor 45. The inner wall of the flow sensor 44 away from the pressure sensor 45 is fixedly connected to the bubble sensor 46, which transmits the soft membrane catheter 23 in the bubble sensor 46 to the abdominal cavity and connects to the soft membrane catheter 23 in the inlet component 1. The end face of the drainage tube 41 away from the drainage valve 42 is fixedly connected to the surface of the bypass valve 21. The end face of the drainage valve 42 away from the drainage tube 41 is fixedly connected to the surface of the drainage tank 8. The inner wall of the bubble sensor 46 is fixedly connected to the soft membrane catheter 23. The end face of the flow sensor 44 away from the pressure sensor 45 is fixedly connected to the surface of the sensor 10. The surface of the soft membrane catheter 23 away from the bubble sensor 46 is in contact with the surface of the drainage peristaltic pump 43.

[0046] An inner slider 47 is fixedly connected to the end face of the membrane housing 25 away from the soft membrane conduit 23. The two inner sliders 47 control the operation of the membrane housing 25. The sensor 10 monitors the soft membrane conduit 23 inside the membrane housing 25 and controls the inflow and outflow of the soft membrane conduit 23. At the same time, when the inner sliders 47 run, they drive the positioning spring 49. A telescopic rod 48 is fixedly connected to the surface of the inner slider 47. When the telescopic rod 48 runs, it controls the inner sliders 47 at both ends to slide along the inner wall of the frame 4. A positioning spring 49 is fixedly connected to the surface of the inner slider 47 away from the telescopic rod 48. The positioning spring 49 then generates... The elastic force provides auxiliary positioning for the positioning spring 49 and guides the liquid inside the device, thus better assisting in the use of the device. There are two inner sliders 47, which are symmetrically distributed around the surface of the telescopic rod 48. There are two telescopic rods 48, which are symmetrically distributed around the surface of the inner sliders 47. There are two positioning springs 49, which are symmetrically distributed around the surface of the inner sliders 47. The surface of the inner sliders 47 is slidably connected to the inner wall of the frame 4. The end face of the positioning spring 49 away from the inner slider 47 is fixedly connected to the inner wall of the frame 4.

[0047] During operation, the liquid transfer valve 11 in the liquid inlet component 1 is activated, transferring the liquid from the two replenishment tanks 6 through the liquid transfer pipe 12. The liquid then flows to the liquid combination pipe 13, which in turn transfers it to the liquid outlet peristaltic pump 14. The pump 14 then discharges the liquid from the liquid combination pipe 13 into the liquid inlet pipe 15. Afterward, the liquid flows to the heating component 2. Once completed in the heating component 2, the heating valve 27 is activated, and the heated liquid flows back to the liquid combination pipe 13 through the heating pipe 26, finally returning to the liquid inlet pipe 15. Simultaneously, the bypass valve 21 operates, allowing the liquid in the liquid inlet pipe 15 to flow out through the bypass pipe 20, thus venting the air in the device to the liquid outlet component 3. Inside, all the air in the device is expelled to prevent the liquid pressure from being affected during use. Then, the inlet valve 17 is activated and the bypass valve 21 is closed, allowing the liquid in the inlet pipe 15 to enter the balance volume chamber 16. Then, the outlet valve 18 is activated, allowing the liquid to enter the outlet pipe 19, and then through the outlet pipe 19 to the infusion pipe 22, and finally to the soft membrane catheter 23. At the same time, the soft membrane catheter 23 is passed through the membrane sleeve 25, and the membrane inside the membrane sleeve 25 covers the surface of the soft membrane catheter 23, guiding the soft membrane catheter 23 into the abdominal cavity for normal use, to infuse the liquid entering the abdominal cavity for fluid replenishment. At this time, when the liquid from the inlet component 1 enters the heating component 2, the replenishing valve 31 is activated, transferring the liquid discharged from the inlet pipe 15 through the replenishing pipe 32, and finally into the heating chamber 33. Simultaneously, the heating control board 7 is activated to heat the liquid entering the heating chamber 33, and at the same time, it drives the output shaft 34 to run. The output shaft 34 then drives the stirring plate 35 to run, which stirs the liquid entering the heating chamber 33, making the liquid in the heating chamber 33 heat more completely and stably. Also, when the output shaft 34 runs, it... When the output helical gear plate 36 operates, it drives the transmission helical gear plate 37 to rotate along the inner wall of the heating box 33 through surface meshing. When the transmission helical gear plate 37 operates, it drives the longitudinal stirring plate 38 to operate. The longitudinal stirring plate 38 guides the liquid in the heating box 33 to operate better. At the same time, when the transmission helical gear plate 37 operates, it drives the stirring teeth 39 to operate. The stirring teeth 39, together with the stirring plate 35, perform better stirring of the liquid in the heating box 33, making the liquid more completely heated.At this time, within the drainage component 3, the soft membrane catheter 23 inside the bubble sensor 46 is transmitted to the abdominal cavity and connected to the soft membrane catheter 23 inside the inlet component 1. Then, sensor 10 controls the flow sensor 44, pressure sensor 45, and bubble sensor 46 to start monitoring the fluid within the soft membrane catheter 23. Simultaneously, when the bypass valve 21 operates, it transmits a signal to the drainage tube 41, then vents the air in the device into the drainage tank 8. Afterwards, the drainage peristaltic pump 43 and drainage valve 42 are activated to control the flow of fluid from the soft membrane catheter 23 into the abdominal cavity. Simultaneously, the telescopic rod 48 operates, controlling the inner sliders 47 at both ends to slide along the inner wall of the frame 4. The two inner sliders 47 then control the operation of the membrane housing 25. The sensor 10 monitors the soft membrane conduit 23 inside the membrane housing 25 and controls the inflow and outflow of the soft membrane conduit 23. At the same time, when the inner sliders 47 operate, they drive the positioning spring 49 to operate. The positioning spring 49 will generate elastic force to assist in positioning and guide the liquid in the device, thus better assisting in the use of the device.

[0048] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.

Claims

1. A multi-channel volumetric tube assembly module, comprising a frame (4), wherein a partition (5) is fixedly connected to the surface of the frame (4), a replenishment tank (6) is fixedly connected to the end face of the partition (5), and a heating control plate (7) is fixedly connected to the inner wall of the partition (5) near the replenishment tank (6), characterized in that, Also includes: Liquid inlet component (1), the liquid inlet component (1) includes a liquid transmission valve (11), a liquid transmission pipe (12) is fixedly connected to the inner wall of the liquid transmission valve (11), and a liquid mixing pipe (13) is fixedly connected to the surface of the liquid transmission pipe (12) away from the liquid transmission valve (11). Heating component (2), the heating component (2) includes a liquid replenishment valve (31), a liquid replenishment pipe (32) is fixedly connected to the inner wall of the liquid replenishment valve (31), and a heating box (33) is fixedly connected to the end face of the liquid replenishment pipe (32) away from the liquid replenishment valve (31). The drainage component (3) includes a drainage tube (41), and a drainage valve (42) is fixedly connected to the end face of the drainage tube (41). A drainage peristaltic pump (43) is fixedly connected to the end face of the drainage valve (42) near the end of the drainage tube (41).

2. The multi-channel volumetric cavity tube module according to claim 1, characterized in that: The surface of the partition (5) near the frame (4) is fixedly connected to a drain tank (8), and the surface of the frame (4) away from the drain tank (8) is fixedly connected to a top cover (9). A sensor (10) is snapped into the inner wall of the top cover (9). There are two partitions (5), which are equidistantly distributed along the surface of the frame (4). There are two replenishment tanks (6), which are symmetrically distributed with respect to the surface of the partitions (5).

3. A multi-channel volumetric cavity tube module according to claim 2, characterized in that: The liquid inlet component (1) includes a liquid outlet peristaltic pump (14), and a liquid inlet pipe (15) is fixedly connected to the end face of the liquid outlet peristaltic pump (14). There are two liquid transfer valves (11), which are symmetrically distributed on the surface of the liquid transfer pipe (12). The end face of the liquid merging pipe (13) away from the liquid transfer pipe (12) is fixedly connected to the surface of the liquid outlet peristaltic pump (14).

4. A multi-channel volumetric cavity tube module according to claim 3, characterized in that: An inlet valve (17) is fixedly connected to the surface of the inlet pipe (15) away from the outlet peristaltic pump (14). A balance volume chamber (16) is fixedly connected to the end face of the inlet valve (17) away from the inlet pipe (15). An outlet valve (18) is fixedly connected to the surface of the balance volume chamber (16) near the inlet valve (17). An outlet pipe (19) is fixedly connected to the inner wall of the outlet valve (18). The surface of the inlet pipe (15) near the inlet valve (17) is fixedly connected to... A bypass pipe (20) is connected, and a bypass valve (21) is fixedly connected to the end face of the bypass pipe (20) away from the inlet valve (17). A heating valve (27) is fixedly connected to the surface of the liquid mixing pipe (13) near the liquid transmission pipe (12). A heating tube (26) is fixedly connected to the surface of the heating valve (27) away from the liquid mixing pipe (13). There are two inlet valves (17), and the two inlet valves (17) are equidistantly distributed along the surface of the inlet pipe (15).

5. A multi-channel volumetric cavity tube module according to claim 4, characterized in that: The end face of the outlet pipe (19) away from the outlet valve (18) is fixedly connected to an infusion pipe (22), and the end face of the infusion pipe (22) away from the outlet pipe (19) is fixedly connected to a soft membrane conduit (23). A transverse shaft plate (24) is rotatably connected to the surface of the soft membrane conduit (23), and a thin film sleeve (25) is provided on the surface of the soft membrane conduit (23) away from the transverse shaft plate (24). There are two soft membrane conduits (23), and the two soft membrane conduits (23) are arranged horizontally. The surface of the shaft plate (24) is symmetrically distributed. The surface of the horizontal shaft plate (24) is located inside the top cover (9). There are two thin film boxes (25). The two thin film boxes (25) are symmetrically distributed along the surface of the top cover (9). The surface of the soft membrane conduit (23) penetrates the surface of the thin film box (25) to the surface of the thin film box (25) away from the horizontal shaft plate (24). The surface of the thin film box (25) away from the horizontal shaft plate (24) is in contact with the surface of the sensor (10).

6. A multi-channel volumetric cavity tube module according to claim 5, characterized in that: The heating component (2) includes an output shaft (34), a stirring plate (35) is fixedly connected to the surface of the output shaft (34), an output helical tooth plate (36) is fixedly connected to the surface of the output shaft (34) near the stirring plate (35), the end face of the replenishing valve (31) away from the replenishing pipe (32) is fixedly connected to the end face of the inlet pipe (15) away from the outlet peristaltic pump (14), the surface of the heating box (33) is set on the surface of the heating control plate (7), the number of stirring plates (35) is set to six, the six stirring plates (35) are divided into two groups, and the number of each group is set to three, the two groups of stirring plates (35) are equidistantly distributed along the surface of the output shaft (34), and the surface of the heating pipe (26) away from the heating valve (27) is fixedly connected to the surface of the heating box (33).

7. A multi-channel volumetric cavity tube module according to claim 6, characterized in that: The output helical tooth plate (36) is meshed with a transmission helical tooth plate (37). A longitudinal stirring plate (38) is fixedly connected to the surface of the transmission helical tooth plate (37) away from the output helical tooth plate (36). A stirring tooth (39) is fixedly connected to the end face of the transmission helical tooth plate (37) away from the longitudinal stirring plate (38). There are two transmission helical tooth plates (37). The two transmission helical tooth plates (37) are symmetrically distributed with respect to the surface of the output helical tooth plate (36). The surface of the transmission helical tooth plate (37) near the longitudinal stirring plate (38) is rotatably connected to the inner wall of the heating box (33).

8. A multi-channel volumetric cavity tube module according to claim 7, characterized in that: The drainage component (3) includes a flow sensor (44), a pressure sensor (45) is fixedly connected to the end face of the flow sensor (44), a bubble sensor (46) is fixedly connected to the inner wall of the flow sensor (44) away from the pressure sensor (45), the end face of the drainage tube (41) away from the drainage valve (42) is fixedly connected to the surface of the bypass valve (21), the end face of the drainage valve (42) away from the drainage tube (41) is fixedly connected to the surface of the drainage tank (8), a soft membrane conduit (23) is fixedly connected to the inner wall of the bubble sensor (46), the end face of the flow sensor (44) away from the pressure sensor (45) is fixedly connected to the surface of the sensor (10), and the surface of the soft membrane conduit (23) away from the bubble sensor (46) is in contact with the surface of the drainage peristaltic pump (43).

9. A multi-channel volumetric cavity tube module according to claim 8, characterized in that: The end face of the membrane housing (25) away from the soft membrane conduit (23) is fixedly connected to an inner slider (47). The surface of the inner slider (47) is fixedly connected to a telescopic rod (48). The surface of the inner slider (47) away from the telescopic rod (48) is fixedly connected to a positioning spring (49). There are two inner sliders (47). The two inner sliders (47) are symmetrically distributed with respect to the surface of the telescopic rod (48). There are two telescopic rods (48). The two telescopic rods (48) are symmetrically distributed with respect to the surface of the inner sliders (47). There are two positioning springs (49). The surface of the inner sliders (47) is slidably connected to the inner wall of the frame (4). The end face of the positioning spring (49) away from the inner slider (47) is fixedly connected to the inner wall of the frame (4).