CN219915456U - Chamber mirror room disinfection monitoring system - Google Patents

Abstract

The utility model discloses a disinfection monitoring system for a cavity mirror chamber, which comprises: the system comprises a monitoring module, a gateway and an Internet of things platform; the monitoring module comprises a disinfectant chloride ion concentration monitoring module, a current monitoring module and a scanning monitoring module; the disinfectant chlorine ion concentration monitoring module is connected with the gateway; the current monitoring module comprises a circulating pump; one end of the circulating pump is connected with the disinfectant chloride ion concentration monitoring module, and the other end of the circulating pump is connected with the gateway; the scanning monitoring module is connected with the gateway; the gateway is connected with the platform of the Internet of things; the internet of things platform is used for managing and storing the processed concentration value, the disinfection state and the use time in real time. The system is used for carrying out real-time disinfection monitoring on the endoscope chamber under the condition of ensuring high accuracy of detecting the concentration of chloride ions in the disinfectant, and also providing current monitoring and endoscope disinfection state monitoring; thus, the omnibearing monitoring can reduce the occurrence of iatrogenic cross infection.

Description

Chamber mirror room disinfection monitoring system

Technical Field

The utility model relates to the technical field of disinfection monitoring, in particular to a cavity mirror chamber disinfection monitoring system.

Background

With the maturation of modern technological development 4G, the innovation of 5G and the appearance of various high-performance precision data acquisition sensors, the application of the internet of things has been expanded to various fields, but has not been applied by the medical industry nowadays. To date: the endoscope disinfection and environment disinfection monitoring of departments such as a dialysis room, a clean operating room and a supply room of a medical institution still uses manual input self-report disinfection data, so that the disinfection monitoring of the departments lacks real-time performance and accuracy, and the objective, real and effective requirement of the health administration management and control of hospital infection risk factors on the disinfection data is not met. Especially in traceability, scientific and reasonable analysis of iatrogenic cross infection.

Disclosure of Invention

Therefore, the technical problem to be solved by the utility model is to overcome the defects in the prior art, so as to provide a cavity disinfection monitoring system.

The utility model provides a disinfection monitoring system for a cavity mirror chamber, which comprises:

the system comprises a monitoring module, a gateway and an Internet of things platform;

the monitoring module comprises a disinfectant chloride ion concentration monitoring module, a current monitoring module and a scanning monitoring module;

the disinfectant chlorine ion concentration monitoring module is connected with the gateway; the disinfectant chlorine ion concentration monitoring module is used for monitoring the concentration value of chlorine ions in the disinfectant and transmitting the concentration value to the gateway;

the current monitoring module comprises a circulating pump; one end of the circulating pump is connected with the disinfectant chloride ion concentration monitoring module, and the other end of the circulating pump is connected with the gateway; the current monitoring module is used for monitoring the service time of the circulating pump during disinfection detection and transmitting the service time to the gateway;

the scanning monitoring module is connected with the gateway; the scanning monitoring module is used for determining decontamination state nodes of the cavity mirror and transmitting decontamination states corresponding to the decontamination state nodes to the gateway;

the gateway is connected with the platform of the Internet of things; the gateway is used for transmitting the received concentration value, the decontamination state corresponding to the decontamination state node and the use time to the Internet of things platform after processing;

the internet of things platform is used for managing and storing the processed concentration value, the disinfection state and the use time in real time.

Preferably, the device also comprises a disinfection tank; the disinfection pond is internally provided with chlorine-containing disinfectant; the input end of the circulating pump extends into the chlorine-containing disinfectant through the first pipeline, and the output end of the circulating pump is communicated with the input end of the disinfectant chlorine-containing ion concentration monitoring module; the circulating pump is used for pumping the chlorine-containing disinfectant into the disinfectant chlorine ion concentration monitoring module; the output end of the disinfectant chloridion concentration monitoring module is communicated with the disinfection tank through a second pipeline.

Preferably, the disinfectant chloride ion concentration monitoring module comprises a working groove and a disinfectant chloride ion concentration detection sensor; the disinfectant chlorine ion concentration detection sensor comprises a test probe and a first signal wire; one end of the working groove is communicated with the first pipeline, and the other end of the working groove is communicated with the second pipeline; the disinfectant chlorine ion concentration detection sensor is arranged in the working groove, one end of the disinfectant chlorine ion concentration detection sensor is connected with the test probe, and the other end of the disinfectant chlorine ion concentration detection sensor is connected with the first signal wire; the test probe is used for detecting the conductivity of the chlorine-containing disinfectant to obtain a concentration value; the other end of the first signal wire is connected with the gateway, and the first signal wire is used for transmitting the concentration value to the gateway.

Preferably, one end of the circulating pump is connected with a power supply sensor, and the other end of the power supply sensor is connected with the gateway through a second signal line; the power supply sensor is used for monitoring the service time of the circulating pump; the second signal line is used to transmit the usage time to the gateway.

Preferably, the scanning monitoring module comprises a two-dimensional code probe and a third signal line; the two-dimensional code probe is used for scanning the two-dimensional code on the endoscope, acquiring the information of the endoscope and determining decontamination state nodes of the endoscope through an RFID technology; one end of the third signal line is connected with the two-dimensional code probe, and the other end of the third signal line is connected with the gateway; the third signal line is used for transmitting the decontamination state corresponding to the decontamination state node to the gateway.

Preferably, the system also comprises a doctor-patient information input module; the doctor-patient information input module comprises android system handheld equipment; the doctor-patient information input module is used for identifying medical personnel information and patient information through an RFID technology, setting the switching authority of the medical personnel, providing a patient information input port and binding a patient with the endoscope; the doctor-patient information input module is connected with the Internet of things platform, and transmits the medical personnel information and the binding information to the Internet of things platform.

Preferably, the concentration value, the decontamination state corresponding to the decontamination state node, the service time, the medical personnel information and the binding information are transmitted to the Internet of things platform after being processed by a data aggregation technology.

Preferably, the decontamination state node comprises a cleaning node, a rinsing node, a disinfection and sterilization node, a final rinsing node and a drying node.

The technical scheme of the utility model has the following advantages: the system is used for carrying out real-time disinfection monitoring on the endoscope chamber under the condition of ensuring high accuracy of detecting the concentration of chloride ions in the disinfectant, and also providing current monitoring and endoscope disinfection state monitoring; thus, the omnibearing monitoring can reduce the occurrence of iatrogenic cross infection.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a monitoring system according to an embodiment of the present utility model.

Fig. 2 is a schematic structural diagram of a monitoring module according to an embodiment of the present utility model.

Fig. 3 is a schematic structural diagram of a module for monitoring chloride ion concentration of a disinfectant according to an embodiment of the present utility model.

Reference numerals illustrate:

1-a monitoring module for chlorine ion concentration of the disinfectant; 11-working groove; 12-detecting the concentration of chloride ions in the disinfectant; 13-a test probe; 14-a first signal line;

2-a current monitoring module; 21-a circulation pump; 22-a power sensor; 23-a second signal line;

3-scanning monitoring module; 31-a two-dimensional code probe; 32-a third signal line;

4-a disinfection tank; 5-a first pipe; 6-a second pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

As shown in fig. 1, the present utility model provides a chamber disinfection monitoring system comprising:

the system comprises a monitoring module, a gateway and an Internet of things platform;

as shown in fig. 2, the monitoring module comprises a disinfectant chloride ion concentration monitoring module 1, a current monitoring module 2 and a scanning monitoring module 3;

the disinfectant chloridion concentration monitoring module 1 is connected with the gateway; the disinfectant chlorine ion concentration monitoring module 1 is used for monitoring the concentration value of chlorine ions in the disinfectant and transmitting the concentration value to the gateway;

the current monitoring module 2 includes a circulation pump 21; one end of the circulating pump 21 is connected with the disinfectant chloride ion concentration monitoring module 1, and the other end of the circulating pump is connected with the gateway; the current monitoring module 2 is used for monitoring the use time of the circulating pump 21 during disinfection detection and transmitting the use time to the gateway;

specifically, one end of the circulating pump 21 is connected with a power supply sensor 22, and the other end of the power supply sensor 22 is connected with the gateway through a second signal line 23; the power sensor 22 is used for monitoring the service time of the circulating pump 21; the second signal line 23 is used to transmit the usage time to the gateway.

The scanning monitoring module 3 is connected with the gateway; the scanning monitoring module 3 is used for determining decontamination state nodes of the cavity mirror and transmitting decontamination states corresponding to the decontamination state nodes to the gateway;

specifically, the scanning monitoring module 3 includes a two-dimensional code probe 31 and a third signal line 32; the two-dimensional code probe 31 is used for scanning the two-dimensional code on the endoscope, acquiring the information of the endoscope and determining the decontamination state node of the endoscope through the RFID technology; one end of the third signal line 32 is connected with the two-dimensional code probe 31, and the other end is connected with the gateway; the third signal line is used for transmitting the decontamination state corresponding to the decontamination state node to the gateway.

The gateway is connected with the platform of the Internet of things; the gateway is used for transmitting the received concentration value, the decontamination state corresponding to the decontamination state node and the use time to the Internet of things platform after processing; concentration value, decontamination state corresponding to decontamination state node, service time, medical personnel information and binding information are transmitted to the internet of things platform after being processed by data aggregation technology.

The system also comprises a doctor-patient information input module; the doctor-patient information input module comprises android system handheld equipment; the doctor-patient information input module is used for identifying medical personnel information and patient information through an RFID technology, setting the switching authority of the medical personnel, providing a patient information input port and binding a patient with the endoscope; the doctor-patient information input module is connected with the Internet of things platform, and transmits the medical personnel information and the binding information to the Internet of things platform.

In this embodiment, the decontamination state nodes include a cleaning node, a rinsing node, a sterilization node, a final rinsing node, and a drying node.

The internet of things platform is used for managing and storing the processed concentration value, the decontamination state corresponding to the decontamination state node and the service time in real time.

Further, the system also comprises a disinfection tank 4; the disinfection tank 4 is internally provided with chlorine-containing disinfectant; the input end of the circulating pump 21 extends into the chlorine-containing disinfectant through the first pipeline 5, and the output end of the circulating pump is communicated with the input end of the disinfectant chlorine-ion concentration monitoring module 1; the circulating pump 21 is used for pumping the chlorine-containing disinfectant into the disinfectant chlorine ion concentration monitoring module 1; the output end of the disinfectant chloridion concentration monitoring module 1 is communicated with the disinfection tank 4 through a second pipeline 6. In the embodiment, a waste discharge port is arranged at the bottom of the disinfection tank 4; the waste liquid is discharged from the waste discharge port at regular intervals, and in this embodiment, is set to be discharged once in 7 days, and the waste liquid is directly discharged into a hospital water pipe network to be treated uniformly.

As shown in fig. 3, the sterilizing liquid chloride ion concentration monitoring module 1 comprises a working tank 11 and a sterilizing liquid chloride ion concentration detection sensor 12; the disinfectant chlorine ion concentration detection sensor 12 comprises a test probe 13 and a first signal wire 14; one end of the working groove 11 is communicated with the first pipeline 5, and the other end is communicated with the second pipeline 6; the disinfectant chlorine ion concentration detection sensor 12 is arranged in the working groove 11, one end of the disinfectant chlorine ion concentration detection sensor is connected with the test probe 13, and the other end of the disinfectant chlorine ion concentration detection sensor is connected with the first signal wire 14; the test probe 13 is used for detecting the conductivity of the chlorine-containing disinfectant to obtain a concentration value; the other end of the first signal line 14 is connected to the gateway, and the first signal line 14 is used for transmitting the concentration value to the gateway.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the utility model.

Claims (8)

1. A system for monitoring disinfection of a chamber, comprising:

the system comprises a monitoring module, a gateway and an Internet of things platform;

the monitoring module comprises a disinfectant chloride ion concentration monitoring module (1), a current monitoring module (2) and a scanning monitoring module (3);

the disinfectant chloride ion concentration monitoring module (1) is connected with the gateway; the disinfectant chloride ion concentration monitoring module (1) is used for monitoring the concentration value of chloride ions in the disinfectant and transmitting the concentration value to the gateway;

the current monitoring module (2) comprises a circulating pump (21); one end of the circulating pump (21) is connected with the disinfectant chloride ion concentration monitoring module (1), and the other end of the circulating pump is connected with the gateway; the current monitoring module (2) is used for monitoring the service time of the circulating pump during disinfection detection and transmitting the service time to the gateway;

the scanning monitoring module (3) is connected with the gateway; the scanning monitoring module (3) is used for determining decontamination state nodes of the endoscope and transmitting decontamination states corresponding to the decontamination state nodes to the gateway;

the gateway is connected with the Internet of things platform; the gateway is used for processing the received concentration value, the decontamination state corresponding to the decontamination state node and the use time and then transmitting the processed decontamination state and the use time to the Internet of things platform;

the internet of things platform is used for managing and storing the processed concentration value, the disinfection state and the use time in real time.

2. The endoscope chamber sterilization monitoring system of claim 1, further comprising a sterilization tank; a chlorine-containing disinfectant is arranged in the disinfection tank (4); the input end of the circulating pump (21) stretches into the chlorine-containing disinfectant through the first pipeline (5), and the output end of the circulating pump is communicated with the input end of the disinfectant chlorine-containing ion concentration monitoring module (1); the circulating pump (21) is used for pumping the chlorine-containing disinfectant into the disinfectant chlorine ion concentration monitoring module (1); the output end of the disinfectant chloride ion concentration monitoring module (1) is communicated with the disinfection tank (4) through a second pipeline (6).

3. A endoscope chamber disinfection monitoring system according to claim 2, characterized in that the disinfection solution chloride ion concentration monitoring module (1) comprises a working tank (11), a disinfection solution chloride ion concentration detection sensor (12); the disinfectant chloride ion concentration detection sensor (12) comprises a test probe (13) and a first signal line (14); one end of the working groove (11) is communicated with the first pipeline (5), and the other end of the working groove is communicated with the second pipeline (6); the disinfectant chlorine ion concentration detection sensor (12) is arranged in the working groove (11), one end of the disinfectant chlorine ion concentration detection sensor is connected with the test probe (13), and the other end of the disinfectant chlorine ion concentration detection sensor is connected with the first signal wire (14); the test probe (13) is used for detecting the conductivity of the chlorine-containing disinfectant to obtain a concentration value; the other end of the first signal line (14) is connected with the gateway, and the first signal line (14) is used for transmitting the concentration value to the gateway.

4. The endoscope chamber disinfection monitoring system according to claim 2, wherein one end of the circulating pump (21) is connected with a power supply sensor (22), and the other end of the power supply sensor (22) is connected with the gateway through a second signal line (23); the power supply sensor (22) is used for monitoring the service time of the circulating pump (21); the second signal line (23) is used for transmitting the usage time to the gateway.

5. The endoscope chamber disinfection monitoring system according to claim 1, wherein the scanning monitoring module (3) comprises a two-dimensional code probe (31) and a third signal line (32); the two-dimensional code probe (31) is used for scanning a two-dimensional code on the endoscope, acquiring information of the endoscope and determining decontamination state nodes of the endoscope through an RFID technology; one end of the third signal line (32) is connected with the two-dimensional code probe (31), and the other end of the third signal line is connected with the gateway; and the third signal line (32) is used for transmitting the decontamination state corresponding to the decontamination state node to the gateway.

6. The endoscope chamber disinfection monitoring system of claim 5, further comprising a doctor-patient information entry module; the doctor-patient information input module comprises android system handheld equipment; the doctor-patient information input module is used for identifying medical personnel information and patient information through an RFID technology, setting the switching authority of the medical personnel, providing a patient information input port and binding a patient with the endoscope; the doctor-patient information input module is connected with the Internet of things platform, and transmits medical personnel information and binding information to the Internet of things platform.

7. The endoscope chamber disinfection monitoring system according to claim 6, wherein the concentration value, the decontamination state corresponding to the decontamination state node, the use time, the medical staff information and the binding information are transmitted to the internet of things platform after being processed by a data aggregation technology.

8. The endoscope chamber sterilization monitoring system of claim 1 wherein the decontamination state node comprises a rinse node, a sterilization node, a terminal rinse node, a dry node.