CN115796082A - Method and system for analyzing drainage data of inner diameter of double-J catheter - Google Patents

Abstract

The invention provides a method and a system for analyzing drainage data of an inner diameter of a double-J catheter, which relate to the technical field of data processing, and the method comprises the following steps: determining first connection information according to the product type of the double J-shaped catheter; outputting a first temperature sensing data set; acquiring a plurality of catheter attribute information of the double-J-shaped catheter, wherein the plurality of catheter attribute information comprises catheter inner diameter information, catheter outer diameter information and catheter material information; obtaining a first drainage rate dataset; analyzing the temperature-rate response relation and outputting a temperature-rate index; predicting the inner diameter drainage time to obtain the predicted time; will the length of prediction is long to be taken notes the storage, has solved exist among the prior art because the analysis procedure to two J type pipe internal diameter drainage data is detailed inadequately, and then leads to the accuracy of pipe internal diameter drainage rate analysis result not enough, to the not good technical problem of the complementary effect of subsequent operation.

Description

Method and system for analyzing drainage data of inner diameter of double-J catheter

Technical Field

The disclosure relates to the technical field of data processing, in particular to a method and a system for analyzing drainage data of the inner diameter of a double-J catheter.

Background

The double J-shaped catheter is a catheter which is conventionally used after urinary system calculus operation, and is mainly used for being placed into a ureter after holmium laser calculus breaking of ureter calculus, percutaneous nephroscope calculus breaking and conventional surgical incision of ureter bladder. The main effect of two J pipes plays the effect of drainage and support, carries out the analysis to two J type pipe internal diameter drainage data, plays complementary effect for the operation of postoperative.

At present, the technical problems that the accuracy of the analysis result of the drainage rate of the inner diameter of the catheter is not enough and the auxiliary effect on subsequent operation is not good exist in the prior art due to the fact that the analysis process of the drainage data of the inner diameter of the double J-shaped catheter is not detailed enough.

Disclosure of Invention

The utility model provides a method and a system for analyzing the drainage data of the inner diameter of a double-J catheter, which are used for solving the technical problems that the accuracy of the analysis result of the drainage rate of the inner diameter of the catheter is not enough and the auxiliary effect of the subsequent operation is not good due to the fact that the analysis process of the drainage data of the inner diameter of the double-J catheter is not detailed enough in the prior art.

According to a first aspect of the present disclosure, there is provided a method for analyzing drainage data of an inner diameter of a double J-shaped catheter, comprising: determining first connection information according to the product type of the double J-shaped catheter; carrying out surface mounting on the temperature sensing device according to the first connection information, and outputting a first sensing temperature data set; acquiring a plurality of catheter attribute information of the double-J-shaped catheter, wherein the plurality of catheter attribute information comprises catheter inner diameter information, catheter outer diameter information and catheter material information; performing drainage rate identification according to the catheter inner diameter information, the catheter outer diameter information and the catheter material information to obtain a first drainage rate data set; analyzing the temperature-rate response relation by using the first sensing temperature data set and the first drainage rate data set, and outputting a temperature-rate index; predicting the inner diameter drainage time length according to the temperature-rate index to obtain the predicted time length; and recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system.

According to a second aspect of the present disclosure, there is provided a dual J-catheter inner diameter drainage data analysis system comprising: a first connection information acquisition module for determining first connection information according to a product type of the double-J catheter; the temperature sensing device setting module is used for carrying out surface mounting setting on the temperature sensing device according to the first connection information and outputting a first sensing temperature data set; a catheter attribute information acquisition module for acquiring a plurality of catheter attribute information of the double-J catheter, wherein the plurality of catheter attribute information includes catheter inner diameter information, catheter outer diameter information, and catheter material information; the drainage rate identification module is used for identifying the drainage rate according to the inner diameter information of the catheter, the outer diameter information of the catheter and the material information of the catheter to obtain a first drainage rate data set; the temperature-rate response relation analysis module is used for analyzing the temperature-rate response relation according to the first transmission temperature data set and the first drainage rate data set and outputting a temperature-rate index; the inner diameter drainage duration prediction module is used for predicting the inner diameter drainage duration according to the temperature-rate index to obtain the predicted duration; and the predicted time length recording and storing module is used for recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system.

According to a third aspect of the present disclosure, there is provided an electronic device comprising:

at least one processor; and

a memory communicatively coupled to the at least one processor; wherein, the first and the second end of the pipe are connected with each other,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of the first aspect.

According to the method for analyzing the drainage data of the inner diameter of the double-J catheter, which is adopted by the disclosure, first connection information is determined according to the product type of the double-J catheter; carrying out surface mounting on the temperature sensing device according to the first connection information, and outputting a first sensing temperature data set; acquiring a plurality of catheter attribute information of the double-J-shaped catheter, wherein the plurality of catheter attribute information comprises catheter inner diameter information, catheter outer diameter information and catheter material information; performing drainage rate identification according to the catheter inner diameter information, the catheter outer diameter information and the catheter material information to obtain a first drainage rate data set; analyzing the temperature-rate response relation by using the first temperature sensing data set and the first drainage rate data set, and outputting a temperature-rate index; predicting the inner diameter drainage time length according to the temperature-rate index to obtain the predicted time length; and recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system. This is disclosed through the material property to the pipe and self structure carry out the analysis, obtains the size of fixed drainage rate, under the different temperatures of further analysis, drainage rate's change to predict when internal diameter drainage is long, it is long when reaching accurate prediction internal diameter drainage, provide the technological effect of auxiliary data for subsequent operation.

It should be understood that the statements in this section do not necessarily identify key or critical features of the embodiments of the present disclosure, nor do they limit the scope of the present disclosure. Other features of the present disclosure will become apparent from the following description.

Drawings

To more clearly illustrate the disclosure or prior art solutions, the drawings needed for the description of the embodiments or prior art will be briefly described below, it is obvious that the drawings in the following description are only exemplary, and that other drawings can be obtained by those skilled in the art without inventive effort from the provided drawings.

Fig. 1 is a schematic flow chart of a method for analyzing drainage data of an inner diameter of a double J-shaped catheter according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart illustrating a process of acquiring a reminder according to an adaptation degree in an embodiment of the present invention;

FIG. 3 is a schematic flow chart of obtaining an optimized predicted duration according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a system for analyzing drainage data of an inner diameter of a double J-shaped catheter according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.

Description of the reference numerals: the device comprises a first connection information acquisition module 11, a temperature sensing device setting module 12, a catheter attribute information acquisition module 13, a drainage rate identification module 14, a temperature-rate response relation analysis module 15, an inner diameter drainage time duration prediction module 16, a prediction time duration record storage module 17, electronic equipment 800, a processor 801, a memory 802 and a bus 803.

Detailed description of the preferred embodiments

Exemplary embodiments of the present disclosure are described below with reference to the accompanying drawings, in which various details of the embodiments of the disclosure are included to assist understanding, and which are to be considered as merely exemplary. Accordingly, those of ordinary skill in the art will recognize that various changes and modifications of the embodiments described herein can be made without departing from the scope and spirit of the present disclosure. Also, descriptions of well-known functions and constructions are omitted in the following description for clarity and conciseness.

In order to solve the technical problems that in the prior art, the accuracy of the analysis result of the drainage rate of the inner diameter of the catheter is not sufficient due to the fact that the analysis process of the drainage data of the inner diameter of the double-J-shaped catheter is not detailed, and the auxiliary effect of the subsequent operation is not good, the inventor of the present disclosure obtains the analysis method and the analysis system of the drainage data of the inner diameter of the double-J-shaped catheter through creative labor.

Examples

Fig. 1 is a diagram of a method for analyzing drainage data of an inner diameter of a double J-shaped catheter, which is provided in an embodiment of the present application, and is applied to a system for analyzing drainage data of an inner diameter of a catheter, the system being in communication connection with a temperature sensing device, as shown in fig. 1, and the method includes:

step S100: determining first connection information according to the product type of the double J-shaped catheter;

specifically, the embodiment of the application provides a method for analyzing drainage data of an inner diameter of a double-J catheter, wherein the double-J catheter is a ureteral stent, the method is applied to a system for analyzing the drainage data of the inner diameter of the catheter, the system for analyzing the drainage data of the inner diameter of the double-J catheter is a system platform for analyzing the drainage data of the inner diameter of the double-J catheter, first connection information is determined according to the product type of the double-J catheter, the product type of the double-J catheter comprises a hippocampal duct, a double-end opening, a single-end opening and the like, and the first connection information means that the double-J catheter is connected with a certain part of a human body, so that liquid is discharged.

Step S200: carrying out surface mounting on the temperature sensing device according to the first connection information, and outputting a first sensing temperature data set;

specifically, the temperature sensing device is a temperature sensor for monitoring the temperature of the part of the human body connected with the double-J catheter, and is generally arranged on the part of the human body connected with the double-J catheter, and a first temperature sensing data set is acquired through the temperature sensing device, and is temperature data acquired by the temperature sensing device.

Step S300: obtaining a plurality of catheter attribute information of the double-J catheter, wherein the plurality of catheter attribute information comprises catheter inner diameter information, catheter outer diameter information and catheter material information;

specifically, the plurality of catheter attribute information refers to information such as the size and the material of the double-J catheter, and the plurality of catheter attribute information is divided into catheter inner diameter information, catheter outer diameter information and catheter material information, specifically, the catheter inner diameter information refers to the size of the inner diameter of the double-J catheter, the catheter outer diameter information refers to the size of the outer diameter of the double-J catheter, and the catheter material information refers to the material of the double-J catheter.

Step S400: performing drainage rate identification according to the catheter inner diameter information, the catheter outer diameter information and the catheter material information to obtain a first drainage rate data set;

specifically, the drainage rate is identified according to the inner diameter information of the catheter, the outer diameter information of the catheter and the material information of the catheter, a first drainage rate data set is obtained, in brief, the size of a fixed drainage rate is output according to the material attribute and the self structure of the catheter, namely, a fixed drainage rate value is obtained according to the outer diameter size and the inner diameter size of the catheter and the smoothness of the inner wall of the material of the catheter, and the drainage rate value is the first drainage rate data set.

Step S500: analyzing the temperature-rate response relation by using the first temperature sensing data set and the first drainage rate data set, and outputting a temperature-rate index;

specifically, the first temperature sensing data set and the first drainage rate data set are analyzed, so that the change of the drainage rate at different temperatures can be obtained, the temperature-rate response relation refers to the influence of the change of the temperature on the drainage rate, the drainage rate is different at different temperatures, and a temperature-rate index is output, wherein the temperature-rate index refers to the corresponding drainage rate at different temperatures.

Step S600: predicting the inner diameter drainage time length according to the temperature-rate index to obtain the predicted time length;

specifically, the inner diameter drainage time duration is predicted according to the temperature-rate index, in short, the liquid amount required to be discharged from the inner cavity is detected, the time duration required for discharging the liquid from the inner cavity is predicted according to the temperature-rate index, the predicted time duration is obtained, and the predicted time duration is the time duration required for discharging the liquid from the inner cavity, so that auxiliary data are provided for the next operation arrangement or treatment means.

Step S700: and recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system.

Specifically, the terminal of the catheter inner diameter drainage data analysis system is installation equipment of the catheter inner diameter drainage data analysis system, the catheter inner diameter drainage data analysis system can be operated through the terminal, the predicted time duration is recorded and stored through the terminal of the catheter inner diameter drainage data analysis system, in brief, the predicted time duration is uploaded to the catheter inner diameter drainage data analysis system, and the technical effect of providing auxiliary data for subsequent operation arrangement or treatment means is achieved.

Based on the analysis, the method for analyzing the drainage data of the inner diameter of the double-J-shaped catheter is provided, in the embodiment, the material property and the self structure of the catheter are analyzed to obtain the size of the fixed drainage rate, and the change of the drainage rate at different temperatures is further analyzed, so that the length of the inner diameter drainage is predicted, the length of the inner diameter drainage is accurately predicted, and the technical effect of providing auxiliary data for subsequent operation is achieved.

As shown in fig. 2, step S800 in the embodiment of the present application further includes:

step S810: acquiring a drainage liquid source according to the first connection information;

step S820: performing liquid characteristic analysis on the drainage liquid source to obtain a plurality of liquid characteristics;

step S830: performing suitability analysis on the double J-shaped catheter according to the multiple liquid characteristics to obtain a suitability index;

step S840: and if the suitability index is smaller than a preset suitability index, acquiring reminding information.

Specifically, the drainage fluid source refers to drainage fluid flowing out of a human body, fluid characteristic analysis is carried out on the drainage fluid source, the color and the consistency of the drainage fluid are analyzed, whether blood clots exist or not, whether the drainage is carried out by using the catheter or not, whether the catheter is blocked or the drainage speed is slow or not and the like are analyzed, a plurality of fluid characteristics are obtained, whether the drainage fluid is suitable for drainage by using the double-J catheter or not is analyzed according to the plurality of fluid characteristics or not, the suitability index refers to the suitability degree of the drainage fluid for drainage by using the double-J catheter or not, then the suitability index is compared with the preset suitability index, the preset suitability index is set according to the actual condition, if the suitability index is larger than the preset suitability index, the drainage fluid is considered to be capable of carrying out drainage by using the double-J catheter, if the suitability index is smaller than the preset suitability index, the preset suitability index is used for reminding a medical staff of reminding the medical staff of changing the drainage fluid to obtain the drainage fluid characteristic, and the drainage fluid characteristic is reminded to change the drainage effect of the double-J catheter.

Wherein, after performing liquid characteristic analysis on the drainage liquid source and obtaining a plurality of liquid characteristics, step S820 in the embodiment of the present application further includes:

step S821: performing stability analysis on the drainage liquid source according to the plurality of liquid characteristics to obtain a stability index;

step S822: if the stability index is smaller than a preset stability index, acquiring a data interception instruction;

step S823: connecting a terminal of the catheter inner diameter drainage data analysis system to obtain a real-time drainage record data set;

step S824: and intercepting the real-time drainage record data set according to the data interception instruction to obtain a screening drainage record data set, so that the duration of the screening drainage record data set is predicted.

Specifically, stability analysis is performed on the drainage liquid source according to a plurality of liquid characteristics, namely stability of the liquid source is analyzed, namely the characteristic change speed of the liquid source, such as high-frequency characteristic change of the drainage liquid source, the stability is low, if the characteristic change of the drainage liquid source is stable, one characteristic is basically maintained, the stability is considered to be high, based on the stability, a stability index is obtained, the stability index is used for representing the stability of the drainage liquid source, whether the stability index is smaller than a preset stability index is judged, the preset stability index can be set according to an actual situation, if the stability index is smaller than the preset stability index, a data interception instruction is obtained, the data interception instruction is used for controlling interception of unstable data of the drainage liquid source, a terminal of a catheter inner diameter drainage data analysis system is connected, a real-time drainage record data set is obtained, the real-time drainage record data set comprises recorded drainage liquid characteristic data, unstable data in the real-time drainage record data set is removed according to the data interception instruction, and accordingly stable data are screened as a drainage record data set, drainage duration prediction is performed according to the drainage record data, unstable prediction time length is realized, stable data is screened, and the accuracy of the removal rate and the prediction effect of the data is improved.

Wherein, according to the catheter inner diameter information, the catheter outer diameter information and the catheter material information, performing drainage rate identification, step S400 of the embodiment of the present application includes:

step S410: analyzing a catheter drainage cavity according to the catheter inner diameter information and the catheter outer diameter information to obtain a fixed drainage rate data set;

step S420: analyzing the influence of the drainage rate of the catheter wall when the temperature changes on the basis of the catheter material information, and outputting a data set influencing the drainage rate;

step S430: outputting the first drainage rate dataset according to the fixed drainage rate dataset and the influenced drainage rate dataset.

Specifically, the drainage rate identification is carried out according to the inner diameter information of the catheter, the outer diameter information of the catheter and the material information of the catheter, the drainage cavity analysis of the catheter is carried out according to the inner diameter information of the catheter and the outer diameter information of the catheter, namely, the inner diameter and the outer diameter of the catheter are larger, more liquid can flow out in unit time, a fixed drainage rate data set is obtained based on the analysis of the fixed liquid outflow speed of the catheter, the fixed drainage rate data set is the fixed liquid outflow speed of the catheter, furthermore, the influence of the drainage rate of the catheter wall during temperature change is analyzed according to the material information of the catheter, the smoothness of the catheter wall and the flow rate of the liquid in the catheter can be influenced along with the temperature change, the change of the flow speed of the liquid in the catheter wall under different temperatures is determined according to the material information of the catheter, the drainage rate influence data set is obtained, the drainage rate influence data set comprises influence values of the catheter wall on the liquid flow speed under different temperatures, and the fixed drainage rate data set is combined with the drainage rate data set to obtain a first drainage rate data set, and the effect of improving the accuracy of the drainage rate analysis is achieved.

Wherein, step S900 in the embodiment of the present application further includes:

step S910: acquiring the double-head bending length of the double-J-shaped guide pipe;

step S920: acquiring identification nodes according to the double-head bending length, wherein the identification nodes comprise a first identification node and a second identification node, the first identification node is a switching node from a bent conduit to an intermediate conduit, and the second identification node is a switching node from the intermediate conduit to the bent conduit;

step S930: and performing segmented storage on the drainage data according to the first identification node and the second identification node.

Specifically, two ends of a catheter of the double J-shaped catheter are provided with bent parts, the drainage rate of the bent parts of the catheter is different from that of the straight parts in the middle, and the drainage rate of the bent parts is slow.

Wherein, performing segmented storage of the drainage data according to the first identification node and the second identification node, as shown in fig. 3, step S930 in this embodiment of the present application further includes:

step S931: outputting a three-stage catheter record dataset comprising a first curved catheter record dataset, an intermediate catheter record dataset, and a second curved catheter record dataset according to the first marker node and the second marker node;

step S932: obtaining a temperature-bending rate index from the first curved conduit record data set and the second curved conduit record data set;

step S933: obtaining a temperature-intermediate rate index from the intermediate catheter record dataset;

step S934: and predicting the inner diameter drainage time length according to the temperature-bending rate index and the temperature-intermediate rate index to obtain the optimized predicted time length.

Specifically, the catheter is divided into three parts according to a first identification node and a second identification node, the three parts are respectively a bent catheter at two ends of the catheter and a straight catheter in the middle, a recorded data set of the catheter corresponding to the three parts is obtained based on the three parts, namely a recorded data set of the three-section catheter is obtained, the recorded data set of the three-section catheter comprises a recorded data set of the first bent catheter, a recorded data set of the middle catheter and a recorded data set of the second bent catheter, and a temperature-bending rate index is obtained according to the recorded data set of the first bent catheter and the recorded data set of the second bent catheter.

Wherein, step S1000 in the embodiment of the present application further includes:

step S1010: acquiring a real-time use environment of the double J-shaped catheter;

step S1020: detecting the temperature of the real-time use environment to obtain environment temperature data;

step S1030: analyzing the influence of the environmental temperature data on the first sensing temperature data set to obtain a temperature influence coefficient;

step S1040: and if the temperature influence coefficient is larger than a preset temperature influence coefficient, acquiring temperature reminding information.

Specifically, the real-time use environment of the double J-shaped catheter is obtained, the real-time use environment includes a place where the double J-shaped catheter is used, such as a hospital ward or an operating room in which area, and then the temperature of the use environment is detected to obtain environment temperature data, the environment temperature data is temperature data corresponding to the real-time use environment of the double J-shaped catheter, the environment temperature data may affect a first sensing temperature data set acquired by a temperature sensing device, so that the temperature of the first sensing temperature data set is increased or decreased, the temperature influence coefficient is used for representing an influence value of the environment temperature data on the first sensing temperature data set, for example, how much the environment temperature data increases or decreases the temperature of the first sensing temperature data set, the temperature influence coefficient and a preset temperature influence coefficient are compared, the preset temperature influence coefficient can be set by itself according to an actual situation, if the temperature influence coefficient is greater than the preset temperature influence coefficient, it is considered that the influence of the environment temperature data on the first sensing temperature data set exceeds an expectation, temperature reminding information needs to be obtained, a worker is reminded that the difference of the current environment temperature difference is large, the drainage operation is easy to cause instability, and the accurate drainage data, thereby ensuring the accuracy of the technical data.

Examples

Based on the same inventive concept as the method for analyzing the drainage data of the inner diameter of the double-J catheter in the previous embodiment, as shown in FIG. 4, the present application further provides a system for analyzing the drainage data of the inner diameter of the double-J catheter, wherein the system is in communication connection with a temperature sensing device, and the system comprises:

a first connection information obtaining module 11, wherein the first connection information obtaining module 11 is configured to determine first connection information according to a product type of the double-J catheter;

the temperature sensing device setting module 12 is configured to perform patch setting on the temperature sensing device according to the first connection information, and output a first sensing temperature data set;

a catheter attribute information obtaining module 13, where the catheter attribute information obtaining module 13 is configured to obtain a plurality of pieces of catheter attribute information of the double-J catheter, where the plurality of pieces of catheter attribute information include catheter inner diameter information, catheter outer diameter information, and catheter material information;

the drainage rate identification module 14 is configured to perform drainage rate identification according to the catheter inner diameter information, the catheter outer diameter information, and the catheter material information, and acquire a first drainage rate data set;

a temperature-rate response relation analysis module 15, where the temperature-rate response relation analysis module 15 is configured to analyze a temperature-rate response relation according to the first sensing temperature data set and the first drainage rate data set, and output a temperature-rate index;

the inner diameter drainage time length prediction module 16 is used for predicting the inner diameter drainage time length according to the temperature-rate index to obtain the predicted time length;

and the predicted time length recording and storing module 17 is used for recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system 17.

Further, the system further comprises:

the drainage liquid source acquisition module is used for acquiring a drainage liquid source according to the first connection information;

the liquid characteristic analysis module is used for carrying out liquid characteristic analysis on the drainage liquid source to obtain a plurality of liquid characteristics;

the suitability analysis module is used for carrying out suitability analysis on the double J-shaped catheter according to the plurality of liquid characteristics to obtain a suitability index;

and the extraction information acquisition module is used for acquiring reminding information if the suitability index is smaller than a preset suitability index.

Further, the system further comprises:

the stability analysis module is used for carrying out stability analysis on the drainage liquid source according to the plurality of liquid characteristics to obtain a stability index;

the data interception instruction acquisition module is used for acquiring a data interception instruction if the stability index is smaller than a preset stability index;

the real-time drainage recording data set acquisition module is used for connecting a terminal of the catheter inner diameter drainage data analysis system to obtain a real-time drainage recording data set;

and the screening drainage record data set acquisition module is used for intercepting the real-time drainage record data set according to the data interception instruction to acquire a screening drainage record data set, so that the screening drainage record data set can predict the time length.

Further, the system further comprises:

a fixed drainage rate data set acquisition module, wherein the fixed drainage rate data set acquisition module is used for analyzing a catheter drainage cavity according to the catheter inner diameter information and the catheter outer diameter information to acquire a fixed drainage rate data set;

the influence drainage rate data set acquisition module is used for analyzing the influence of the drainage rate of the catheter wall when the temperature changes based on the catheter material information and outputting a data set of the influence drainage rate;

a comprehensive analysis module for outputting the first drainage rate dataset according to the fixed drainage rate dataset and the influenced drainage rate dataset.

Further, the system further comprises:

a double-headed bending length acquisition module for acquiring a double-headed bending length of the double J-shaped conduit;

an identification node obtaining module, configured to obtain an identification node according to the double-headed bending length, where the identification node includes a first identification node and a second identification node, the first identification node is a switching node from a bent conduit to an intermediate conduit, and the second identification node is a switching node from the intermediate conduit to the bent conduit;

and the drainage data segmented storage module is used for performing segmented storage on the drainage data according to the first identification node and the second identification node.

Further, the system further comprises:

a three-stage catheter record dataset acquisition module for outputting a three-stage catheter record dataset comprising a first curved catheter record dataset, an intermediate catheter record dataset, and a second curved catheter record dataset according to the first identification node and the second identification node;

a temperature-bending rate index acquisition module for acquiring a temperature-bending rate index from the first curved conduit record data set and the second curved conduit record data set;

a temperature-intermediate rate index acquisition module to acquire a temperature-intermediate rate index from the intermediate catheter record dataset;

and the optimized prediction duration acquisition module is used for predicting the inner diameter drainage duration according to the temperature-bending rate index and the temperature-intermediate rate index to acquire the optimized prediction duration.

Further, the system further comprises:

a real-time usage environment acquisition module for acquiring a real-time usage environment of the double J-shaped catheter;

the temperature detection module is used for detecting the temperature of the real-time use environment to acquire environment temperature data;

the temperature influence coefficient acquisition module is used for analyzing the influence of the environment temperature data on the first sensing temperature data set to acquire a temperature influence coefficient;

the temperature reminding information acquisition module is used for acquiring temperature reminding information if the temperature influence coefficient is larger than a preset temperature influence coefficient.

A specific example of the method for analyzing drainage data of an inner diameter of a double J-shaped catheter in the first embodiment is also applicable to the system for analyzing drainage data of an inner diameter of a double J-shaped catheter in the present embodiment, and a person skilled in the art can clearly know the system for analyzing drainage data of an inner diameter of a double J-shaped catheter through the foregoing detailed description of the method for analyzing drainage data of an inner diameter of a double J-shaped catheter, so that the detailed description is omitted here for the sake of brevity. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

Examples

Fig. 5 is a schematic diagram according to a third embodiment of the present disclosure, and as shown in fig. 5, an electronic device 800 in the present disclosure may include: a processor 801 and a memory 802.

A memory 802 for storing programs; the Memory 802 may include a volatile Memory (RAM), such as a Static Random Access Memory (SRAM), a Double Data Rate Synchronous Dynamic Random Access Memory (DDR SDRAM), and the like; the memory may also comprise a non-volatile memory, such as a flash memory. The memory 802 is used to store computer programs (e.g., applications, functional modules, etc. that implement the above-described methods), computer instructions, etc., which may be stored in one or more of the memories 802 in a partitioned manner. And the above-described computer programs, computer instructions, data, and the like can be called by the processor 801.

The computer programs, computer instructions, etc. described above may be stored in one or more memories 802 in partitions. And the above-mentioned computer program, computer instruction, or the like can be called by the processor 801.

A processor 801 for executing the computer program stored in the memory 802 to implement the steps of the method according to the above embodiments.

Reference may be made in particular to the description relating to the preceding method embodiment.

The processor 801 and the memory 802 may be separate structures or may be integrated structures integrated together. When the processor 801 and the memory 802 are separate structures, the memory 802 and the processor 801 may be coupled by a bus 803.

The electronic device of this embodiment may execute the technical solution in the method, and the specific implementation process and technical principle are the same, which are not described herein again.

The present disclosure also provides an electronic device, a readable storage medium, and a computer program product according to embodiments of the present disclosure.

According to an embodiment of the present disclosure, the present disclosure also provides a computer program product comprising: a computer program, stored in a readable storage medium, from which at least one processor of the electronic device can read the computer program, the at least one processor executing the computer program causing the electronic device to perform the solution provided by any of the embodiments described above.

It should be understood that various forms of the flows shown above may be used, with steps reordered, added, or deleted. For example, the steps described in this disclosure may be performed in parallel, sequentially or in a different order,

the disclosure is not limited thereto so long as it achieves the desired results of the presently disclosed embodiments.

The above detailed description should not be construed as limiting the scope of the disclosure. It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and substitutions may be made in accordance with design requirements and other factors. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present disclosure should be included in the scope of protection of the present disclosure.

Claims (9)

1. A method for analyzing drainage data of an inner diameter of a double-J type catheter, which is applied to a system for analyzing drainage data of the inner diameter of the catheter, wherein the system is connected with a temperature sensing device in a communication way, and the method comprises the following steps:

determining first connection information according to the product type of the double J-shaped catheter;

carrying out surface mounting on the temperature sensing device according to the first connection information, and outputting a first sensing temperature data set;

acquiring a plurality of catheter attribute information of the double-J-shaped catheter, wherein the plurality of catheter attribute information comprises catheter inner diameter information, catheter outer diameter information and catheter material information;

performing drainage rate identification according to the catheter inner diameter information, the catheter outer diameter information and the catheter material information to obtain a first drainage rate data set;

analyzing the temperature-rate response relation by using the first sensing temperature data set and the first drainage rate data set, and outputting a temperature-rate index;

predicting the inner diameter drainage time length according to the temperature-rate index to obtain the predicted time length;

and recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system.

2. The method of claim 1, wherein the method further comprises:

acquiring a drainage liquid source according to the first connection information;

performing liquid characteristic analysis on the drainage liquid source to obtain a plurality of liquid characteristics;

carrying out adaptation degree analysis on the double J-shaped catheter according to the plurality of liquid characteristics to obtain an adaptation degree index;

and if the adaptation index is smaller than a preset adaptation index, acquiring reminding information.

3. The method of claim 2, wherein after performing a fluid characterization analysis on the source of drain fluid to obtain a plurality of fluid characterizations, the method further comprises:

performing stability analysis on the drainage liquid source according to the plurality of liquid characteristics to obtain a stability index;

if the stability index is smaller than a preset stability index, acquiring a data interception instruction;

connecting a terminal of the catheter inner diameter drainage data analysis system to obtain a real-time drainage record data set;

and intercepting the real-time drainage record data set according to the data interception instruction to obtain a screening drainage record data set, so that the duration of the screening drainage record data set is predicted.

4. The method of claim 1, wherein performing drainage rate identification based on the catheter inner diameter information, the catheter outer diameter information, and the catheter material information, the method further comprises:

analyzing a catheter drainage cavity according to the catheter inner diameter information and the catheter outer diameter information to obtain a fixed drainage rate data set;

analyzing the influence of the drainage rate of the catheter wall when the temperature changes based on the catheter material information, and outputting a data set influencing the drainage rate;

outputting the first drainage rate dataset according to the fixed drainage rate dataset and the influenced drainage rate dataset.

5. The method of claim 4, wherein the method further comprises:

acquiring the double-head bending length of the double-J-shaped guide pipe;

acquiring an identification node according to the double-end bending length, wherein the identification node comprises a first identification node and a second identification node, the first identification node is a switching node from a bent conduit to an intermediate conduit, and the second identification node is a switching node from the intermediate conduit to the bent conduit;

and performing segmented storage of the drainage data according to the first identification node and the second identification node.

6. The method of claim 5, wherein the storing of the segments of the drainage data is based on the first identified node and the second identified node, the method further comprising:

outputting a three-stage catheter record dataset comprising a first curved catheter record dataset, an intermediate catheter record dataset, and a second curved catheter record dataset based on the first identified node and the second identified node;

obtaining a temperature-bending rate indicator from the first curved catheter recorded dataset and the second curved catheter recorded dataset;

obtaining a temperature-intermediate rate index from the intermediate catheter record dataset;

and predicting the inner diameter drainage time length according to the temperature-bending rate index and the temperature-intermediate rate index to obtain the optimized predicted time length.

7. The method of claim 1, wherein the method further comprises:

acquiring a real-time use environment of the double J-shaped catheter;

detecting the temperature of the real-time use environment to obtain environment temperature data;

analyzing the influence of the environmental temperature data on the first sensing temperature data set to obtain a temperature influence coefficient;

and if the temperature influence coefficient is larger than a preset temperature influence coefficient, acquiring temperature reminding information.

8. A dual J-catheter inner diameter drainage data analysis system, wherein the system is communicatively coupled to a temperature sensing device, the system comprising:

a first connection information acquisition module for determining first connection information according to a product type of the double-J catheter;

the temperature sensing device setting module is used for carrying out surface mounting setting on the temperature sensing device according to the first connection information and outputting a first sensing temperature data set;

a catheter attribute information acquisition module for acquiring a plurality of catheter attribute information of the double-J catheter, wherein the plurality of catheter attribute information includes catheter inner diameter information, catheter outer diameter information, and catheter material information;

the drainage rate identification module is used for identifying the drainage rate according to the inner diameter information of the catheter, the outer diameter information of the catheter and the material information of the catheter to obtain a first drainage rate data set;

the temperature-rate response relation analysis module is used for analyzing the temperature-rate response relation according to the first transmission temperature data set and the first drainage rate data set and outputting a temperature-rate index;

the inner diameter drainage duration prediction module is used for predicting the inner diameter drainage duration according to the temperature-rate index to obtain the predicted duration;

and the predicted time length recording and storing module is used for recording and storing the predicted time length through a terminal of the catheter inner diameter drainage data analysis system.

9. An electronic device, comprising:

at least one processor; and

a memory communicatively coupled to the at least one processor; wherein the content of the first and second substances,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of any one of claims 1-7.

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