CN112666344B - Medical-defense fusion-based working method for remotely screening and extracting case data of diabetes high-risk group - Google Patents
Medical-defense fusion-based working method for remotely screening and extracting case data of diabetes high-risk group Download PDFInfo
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- 238000000034 method Methods 0.000 title claims abstract description 28
- 206010012601 diabetes mellitus Diseases 0.000 title claims abstract description 20
- 238000012216 screening Methods 0.000 title claims abstract description 18
- 230000004927 fusion Effects 0.000 title claims abstract description 9
- 238000001514 detection method Methods 0.000 claims abstract description 55
- UGFAIRIUMAVXCW-UHFFFAOYSA-N Carbon monoxide Chemical compound [O+]#[C-] UGFAIRIUMAVXCW-UHFFFAOYSA-N 0.000 claims abstract description 27
- 229910002091 carbon monoxide Inorganic materials 0.000 claims abstract description 27
- 238000005259 measurement Methods 0.000 claims abstract description 20
- CSCPPACGZOOCGX-UHFFFAOYSA-N Acetone Chemical compound CC(C)=O CSCPPACGZOOCGX-UHFFFAOYSA-N 0.000 claims abstract description 8
- 239000007789 gas Substances 0.000 claims description 127
- 238000004062 sedimentation Methods 0.000 claims description 119
- 238000002485 combustion reaction Methods 0.000 claims description 58
- 239000007788 liquid Substances 0.000 claims description 56
- 238000001914 filtration Methods 0.000 claims description 47
- 230000005540 biological transmission Effects 0.000 claims description 43
- 238000004140 cleaning Methods 0.000 claims description 27
- CURLTUGMZLYLDI-UHFFFAOYSA-N Carbon dioxide Chemical compound O=C=O CURLTUGMZLYLDI-UHFFFAOYSA-N 0.000 claims description 24
- 239000002699 waste material Substances 0.000 claims description 16
- 230000006698 induction Effects 0.000 claims description 14
- 229910002092 carbon dioxide Inorganic materials 0.000 claims description 12
- 239000001569 carbon dioxide Substances 0.000 claims description 12
- 239000000243 solution Substances 0.000 claims description 12
- 238000006243 chemical reaction Methods 0.000 claims description 11
- 239000002912 waste gas Substances 0.000 claims description 10
- 238000012795 verification Methods 0.000 claims description 9
- 230000003141 anti-fusion Effects 0.000 claims description 8
- 230000004584 weight gain Effects 0.000 claims description 8
- 235000019786 weight gain Nutrition 0.000 claims description 8
- WDIHJSXYQDMJHN-UHFFFAOYSA-L barium chloride Chemical compound [Cl-].[Cl-].[Ba+2] WDIHJSXYQDMJHN-UHFFFAOYSA-L 0.000 claims description 6
- 229910001626 barium chloride Inorganic materials 0.000 claims description 6
- 239000012047 saturated solution Substances 0.000 claims description 6
- 238000010926 purge Methods 0.000 claims description 5
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- 229910001628 calcium chloride Inorganic materials 0.000 claims description 4
- 239000001110 calcium chloride Substances 0.000 claims description 4
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- 201000001421 hyperglycemia Diseases 0.000 description 2
- NOESYZHRGYRDHS-UHFFFAOYSA-N insulin Chemical compound N1C(=O)C(NC(=O)C(CCC(N)=O)NC(=O)C(CCC(O)=O)NC(=O)C(C(C)C)NC(=O)C(NC(=O)CN)C(C)CC)CSSCC(C(NC(CO)C(=O)NC(CC(C)C)C(=O)NC(CC=2C=CC(O)=CC=2)C(=O)NC(CCC(N)=O)C(=O)NC(CC(C)C)C(=O)NC(CCC(O)=O)C(=O)NC(CC(N)=O)C(=O)NC(CC=2C=CC(O)=CC=2)C(=O)NC(CSSCC(NC(=O)C(C(C)C)NC(=O)C(CC(C)C)NC(=O)C(CC=2C=CC(O)=CC=2)NC(=O)C(CC(C)C)NC(=O)C(C)NC(=O)C(CCC(O)=O)NC(=O)C(C(C)C)NC(=O)C(CC(C)C)NC(=O)C(CC=2NC=NC=2)NC(=O)C(CO)NC(=O)CNC2=O)C(=O)NCC(=O)NC(CCC(O)=O)C(=O)NC(CCCNC(N)=N)C(=O)NCC(=O)NC(CC=3C=CC=CC=3)C(=O)NC(CC=3C=CC=CC=3)C(=O)NC(CC=3C=CC(O)=CC=3)C(=O)NC(C(C)O)C(=O)N3C(CCC3)C(=O)NC(CCCCN)C(=O)NC(C)C(O)=O)C(=O)NC(CC(N)=O)C(O)=O)=O)NC(=O)C(C(C)CC)NC(=O)C(CO)NC(=O)C(C(C)O)NC(=O)C1CSSCC2NC(=O)C(CC(C)C)NC(=O)C(NC(=O)C(CCC(N)=O)NC(=O)C(CC(N)=O)NC(=O)C(NC(=O)C(N)CC=1C=CC=CC=1)C(C)C)CC1=CN=CN1 NOESYZHRGYRDHS-UHFFFAOYSA-N 0.000 description 2
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Abstract
The invention provides a medical fusion-based remote screening and extracting working method for case data of diabetes high risk group, which comprises the following steps: s1, initializing a system; s2, acquiring measurement data of a user to be measured; and S3, sending the measurement data in the step S2 to a remote server terminal. The invention can convert the acetone contained in the exhaled air of the user into carbon monoxide, realize detection by the gas sensor and finally send the data to the user.
Description
Technical Field
The invention relates to the technical field of data screening, in particular to a medical-defense fusion-based remote screening and extracting working method for case data of a diabetes high-risk group.
Background
Diabetes is a metabolic disease characterized by hyperglycemia due to insulin secretion deficiency or insulin action disorder. Sustained hyperglycemia and long-term metabolic disorders, etc. can lead to damage to systemic tissue and organs, particularly the eye, kidneys, cardiovascular and nervous systems, and to dysfunction and failure thereof. Patent application number 2019112958781, the name is "a diabetes urine sugar detection device and method of use thereof", has disclosed to accept kettle, open bowl portion and buret portion, it is formed with in the kettle to accept the chamber, open bowl portion set up in accept the top of kettle to link up in the middle part and seted up the inlet port, the inlet port with accept the inner chamber intercommunication of kettle, buret portion's one end connect in accept the bottom of kettle, the other end slope upper extension down, buret portion's top position is higher than accept the top of kettle, buret portion is used for acceping the test paper. The patent application determines diabetes by a test strip color change.
Disclosure of Invention
The invention aims at least solving the technical problems in the prior art, and particularly creatively provides a working method for remotely screening and extracting case data of high-risk diabetes groups based on medical and anti-fusion.
In order to achieve the above purpose, the invention provides a medical anti-fusion based remote screening and extracting working method for case data of diabetes high risk group, which comprises the following steps:
s1, initializing a system;
s2, acquiring measurement data of a user to be measured;
and S3, sending the measurement data in the step S2 to a remote server terminal.
In a preferred embodiment of the present invention, the first to twelfth solenoid valves are normally closed solenoid valves, and step S1 includes the steps of:
s11, detecting whether the weight increment of the filter chamber or/and the weight increment of the sedimentation chamber is greater than or equal to a preset weight increment threshold value of the filter chamber and a preset weight increment threshold value of the sedimentation chamber corresponding to the weight increment threshold value of the filter chamber or/and the weight increment threshold value of the sedimentation chamber:
if the weight increase of the filter chamber is greater than or equal to the preset weight increase threshold of the filter chamber, a warning is sent out, and the filter chamber solution is added into the filter chamber;
if the weight gain of the sedimentation chamber is larger than or equal to the preset weight gain threshold value of the sedimentation chamber, a warning is sent out, and the sedimentation chamber solution is added into the sedimentation chamber;
Otherwise, executing the next step;
s12, the controller controls the gas release device to release the cleaning gas; the controller sequentially and respectively sends a conduction control command to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve according to the sequence; the closed pipeline is conducted;
s13, removing impurity gases in the generating chamber, the filtering chamber, the combustion chamber and the sedimentation chamber by the gas to be cleaned; the controller respectively sends a closing control signal to the seventh electromagnetic valve and the fourth electromagnetic valve, and then respectively sends closing control commands to the second electromagnetic valve, the third electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve and the eighth electromagnetic valve; after the second electromagnetic valve seals the pipeline, the controller controls the gas release device to stop releasing the cleaning gas;
s14, the controller collects the weight of the filter chamber and the weight of the sedimentation chamber at the moment as the initial metering weight of the filter chamber and the initial metering weight of the sedimentation chamber respectively.
In a preferred embodiment of the present invention, the following steps are included in step S2:
s21, acquiring identity information of a user to be tested; after the identity information of the user to be detected is obtained, executing the next step;
S22, if the controller detects that the induction sensor sends out an induction signal, the controller respectively sends out a conduction control command to the first electromagnetic valve and the second electromagnetic valve to conduct the closed pipeline; introducing the gas exhaled by the user to be tested into a generation chamber;
s23, if the controller does not detect that the induction sensor sends out an induction signal, the controller respectively sends out a closing control command to the first electromagnetic valve to close the pipeline; the controller controls the gas release device to release the cleaning gas; t is t 1 After s time, t is 1 S is a positive number greater than 0, s is a time unit of seconds, and the controller controls the gas release device to stop releasing the cleaning gas;
s24, after the gas in the generation chamber reacts, the controller sends a conduction control command to the third electromagnetic valve to conduct the conduit;
s25, if the gas sensor does not detect carbon monoxide, the controller sequentially sends a conduction control command to the eighth electromagnetic valve and the thirteenth electromagnetic valve to conduct the fifth connecting conduit and the eighth connecting conduit, and exhaust gas of the fifth connecting conduit and the eighth connecting conduit is discharged out of the detection box body; after the waste gas is discharged out of the detection box body, the controller sends a closing control command to the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve to close the guide pipe; returning to step S21 or S22;
If the gas sensor detects carbon monoxide, the controller sends a conduction control command to the fourth electromagnetic valve and the fifth electromagnetic valve, and the gas exhaled by a user is converted into carbon monoxide gas to be introduced into the filter chamber through the generating chamber of the controller, and then enters the combustion chamber;
s26, after the gas in the filter chamber enters the combustion chamber, the controller sends a closed control command to the fifth electromagnetic valve to convert carbon monoxide entering the combustion chamber into carbon dioxide, after the conversion is completed, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve, and the gas after the conversion of the combustion chamber is introduced into the sedimentation chamber and then discharged out of the detection box body; after the gas is exhausted, the controller sends a closing control command to the eighth electromagnetic valve to close the pipeline;
s27, calculating the change amount of the sedimentation chamber:
Q=Q 1 -Q 0 ,
wherein Q represents the variation of the sedimentation chamber;
Q 1 indicating the weight detected by the second pressure sensor after the gas enters the settling chamber;
Q 0 indicating the weight of the gas detected by the second pressure sensor before it enters the settling chamber.
In a preferred embodiment of the present invention, the following steps are included in step S21:
s211, if the controller receives the work trigger signal of the ID reading module, the controller sends a work control signal to the ID reading module, and the ID reading module acquires the ID card information of the ID card, wherein the ID card comprises one or any combination of an identity card, a social security medical card and a bank card; the ID card information comprises a user ID card number;
S212, carrying out data processing on the user ID card number;
s213, the obtained new ID card number is sent to a remote server terminal for verification:
if the new identification card number exists in the remote server terminal, sending a verification passing code to the detection box body;
if the new identification card number does not exist in the remote server terminal, the new identification card number is stored in a database of the remote server terminal, and a verification passing code is sent to the detection box body.
In a preferred embodiment of the present invention, the following steps are included in step S3:
s31, transmitting the data obtained by measurement and identity information corresponding to the data obtained by measurement to a remote server terminal;
s32, after the remote server terminal receives the data obtained by measurement and the identity information corresponding to the data obtained by measurement, the remote server terminal inquires the mobile phone number associated with the identity information of the remote server terminal, and the measured data of the remote server terminal is sent to the mobile intelligent handheld terminal through the mobile phone number.
In a preferred embodiment of the present invention, if the gas sensor does not detect carbon monoxide, the controller sequentially transmits a turn-on control command to the eighth solenoid valve and the thirteenth solenoid valve to turn on the fifth connection conduit and the eighth connection conduit thereof, and the controller controls the gas release device to release the purge gas, and then transmits a turn-on control command to the second solenoid valve to discharge the exhaust gas thereof out of the detection case; after the waste gas is discharged out of the detection box body, the controller sends a closing control command to the second electromagnetic valve, the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve so that the guide pipe of the waste gas is closed; the controller controls the gas release device to stop releasing the cleaning gas, and returns to the step S21 or S22;
S26, after the gas in the filter chamber enters the combustion chamber, the controller sends a closing control command to the fifth electromagnetic valve to convert carbon monoxide entering the combustion chamber into carbon dioxide, after the conversion is completed, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve, and the controller controls the gas release device to release cleaning gas, and then sends a conduction control command to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve, and the gas after the conversion of the combustion chamber is introduced into the sedimentation chamber and then is discharged out of the detection box; after the gas is exhausted, the controller controls the gas release device to stop releasing the cleaning gas; the controller sends closing control commands to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve to close the pipeline.
In a preferred embodiment of the present invention, when the controller receives the trigger signal for cleaning and adding liquid in the filter chamber, the method comprises the following steps:
s41, the controller vibrates the pump operation T to the filter chamber installed in the filter chamber 1 s, the T 1 S is a positive number greater than or equal to 0, s is a time unit second, the controller sends a conduction control command to the ninth electromagnetic valve to conduct the seventh connecting conduit, the waste liquid in the filter chamber is discharged out of the filter chamber, after the waste liquid in the filter chamber is discharged out of the filter chamber, the controller sends stop information to the vibration pump of the filter chamber, and sends a closing control command to the ninth electromagnetic valve;
S42, after the vibration pump of the filtering chamber stops working and the seventh connecting conduit is closed, the controller sends a conduction control command to the eleventh electromagnetic valve to conduct the eleventh connecting conduit, and liquid is added into the filtering chamber through the liquid inlet of the filtering chamber; after the liquid adding is completed, the controller sends a closing control command to an eleventh electromagnetic valve to close the guide pipe;
when the controller receives the cleaning and liquid adding trigger signal of the sedimentation chamber, the method comprises the following steps:
s43, the controller operates the vibration pump T of the settling chamber installed in the settling chamber 2 s, the T 2 S is a positive number greater than or equal to 0, s is a time unit second, the controller sends a conduction control command to a tenth electromagnetic valve to conduct a ninth connecting conduit, waste liquid in a sedimentation chamber is discharged out of the sedimentation chamber, after the waste liquid in the sedimentation chamber is discharged out of the sedimentation chamber, the controller sends stop information to a sedimentation chamber vibration pump, and sends a closing control command to the tenth electromagnetic valve;
s44, after the vibration pump of the sedimentation chamber stops working and the ninth connecting conduit is closed, the controller sends a conduction control command to the twelfth electromagnetic valve to conduct the tenth connecting conduit, and liquid is added into the sedimentation chamber through the liquid inlet of the sedimentation chamber; after the liquid adding is completed, the controller sends a closing control command to the twelfth electromagnetic valve to close the guide pipe.
In summary, by adopting the technical scheme, the invention can convert the acetone contained in the gas exhaled by the user into carbon monoxide, realize detection by the gas sensor and finally send the data to the user.
Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.
Drawings
The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:
fig. 1 is a schematic block diagram of a flow of the present invention.
Fig. 2 is a schematic structural view of the present invention.
Detailed Description
Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.
The invention discloses a medical fusion-based working method for remotely screening and extracting case data of high-risk diabetes groups, which is shown in fig. 1 and comprises the following steps:
S1, initializing a system;
s2, acquiring measurement data of a user to be measured;
and S3, sending the measurement data in the step S2 to a remote server terminal.
In a preferred embodiment of the invention, the first to twelfth electromagnetic valves are all normally closed electromagnetic valves, i.e. the controllers send closing control commands to the first to twelfth electromagnetic valves, and the pipelines corresponding to the first to twelfth electromagnetic valves are in pipeline closing states; when the controllers send a conduction control command to the first electromagnetic valve to the twelfth electromagnetic valve, the pipelines corresponding to the first electromagnetic valve to the twelfth electromagnetic valve are in a pipeline conduction state; the step S1 includes the steps of:
s11, detecting whether the weight increment of the filter chamber or/and the weight increment of the sedimentation chamber is greater than or equal to a preset weight increment threshold value of the filter chamber and a preset weight increment threshold value of the sedimentation chamber corresponding to the weight increment threshold value of the filter chamber or/and the weight increment threshold value of the sedimentation chamber:
if the filter chamber weight gain is greater than or equal to the preset filter chamber weight gain threshold, a warning is sent to request the filter chamber 25 to be added with filter chamber solution; the filter chamber solution is a saturated solution of barium chloride.
If the weight gain of the sedimentation chamber is larger than or equal to the preset weight gain threshold value of the sedimentation chamber, a warning is sent out, and the sedimentation chamber solution is added into the sedimentation chamber 3; the solution in the precipitation chamber is saturated solution of barium chloride.
Otherwise, executing the next step;
s12, the controller controls the gas release device to release the cleaning gas; the controller then sends out a conduction control command to the second electromagnetic valve 18, the third electromagnetic valve, the fourth electromagnetic valve 17, the fifth electromagnetic valve 27, the sixth electromagnetic valve, the seventh electromagnetic valve 8 and the eighth electromagnetic valve in sequence; the closed pipeline is conducted;
s13, removing impurity gases in the generating chamber 21, the filtering chamber 25, the combustion chamber 29 and the settling chamber 3 by the gas to be cleaned; the controller respectively sends a closing control signal to the seventh electromagnetic valve 8 and the fourth electromagnetic valve 17, and then respectively sends closing control commands to the second electromagnetic valve 18, the third electromagnetic valve, the fifth electromagnetic valve 27, the sixth electromagnetic valve and the eighth electromagnetic valve; after the second electromagnetic valve 18 closes the pipeline, the controller controls the gas release device to stop releasing the cleaning gas;
s14, the controller collects the weight of the filter chamber and the weight of the sedimentation chamber at the moment as the initial metering weight of the filter chamber and the initial metering weight of the sedimentation chamber respectively.
In a preferred embodiment of the present invention, the following steps are included in step S2:
s21, acquiring identity information of a user to be tested; after the identity information of the user to be detected is obtained, executing the next step;
S22, if the controller detects that the induction sensor sends out induction signals, the controller respectively sends out a conduction control command to the first electromagnetic valve and the second electromagnetic valve 18 to conduct the closed pipeline; the gas exhaled by the user to be tested is introduced into the generation chamber 21;
s23, if the controller does not detect that the induction sensor sends out an induction signal, the controller respectively sends out a closing control command to the first electromagnetic valve to close the pipeline; the controller controls the gas release device to release the cleaning gas; t is t 1 After s time, t is 1 Positive number greater than 0, s is time unit seconds, t 1 Taking 0.5 to 1.5. The controller controls the gas release device to stop releasing the cleaning gas;
s24, after the gas in the generation chamber 21 reacts, the controller sends a conduction control command to the third electromagnetic valve to conduct the conduit;
s25, if the gas sensor 15 does not detect carbon monoxide, the controller sequentially sends a conduction control command to the eighth electromagnetic valve and the thirteenth electromagnetic valve 14 to conduct the fifth connecting conduit 5 and the eighth connecting conduit 9, and exhaust gas of the fifth connecting conduit 5 and the eighth connecting conduit 9 is discharged out of the detection box 6; after the waste gas is discharged out of the detection box body 6, the controller sends a closing control command to the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve 14 to close the guide pipe; returning to step S21 or S22;
If the gas sensor 15 detects carbon monoxide, the controller sends a conduction control command to the fourth electromagnetic valve 17 and the fifth electromagnetic valve 27, and the generation chamber 21 converts the gas exhaled by the user into carbon monoxide gas, and the carbon monoxide gas is introduced into the filter chamber 25 and then enters the combustion chamber 29;
s26, after the gas in the filter chamber 25 enters the combustion chamber 29, the controller sends a closing control command to the fifth electromagnetic valve 27 to convert carbon monoxide entering the combustion chamber 29 into carbon dioxide, after the conversion is completed, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve 8 and the eighth electromagnetic valve, and the gas after the conversion of the combustion chamber 29 is introduced into the sedimentation chamber 3 and then discharged out of the detection box 6; after the gas is exhausted, the controller sends a closing control command to the eighth electromagnetic valve to close the pipeline;
s27, calculating the change amount of the sedimentation chamber:
Q=Q 1 -Q 0 ,
wherein Q represents the variation of the sedimentation chamber;
Q 1 indicating the weight detected by the second pressure sensor after the gas enters the settling chamber;
Q 0 indicating the weight of the gas detected by the second pressure sensor before it enters the settling chamber.
In a preferred embodiment of the present invention, the following steps are included in step S21:
s211, if the controller receives the work trigger signal of the ID reading module, the controller sends a work control signal to the ID reading module, and the ID reading module acquires the ID card information of the ID card, wherein the ID card comprises one or any combination of an identity card, a social security medical card and a bank card; the ID card information comprises a user ID card number;
S212, data processing is carried out on the user ID card number, and the processing mode is as follows:
s2121, selecting a continuous digit number as k, wherein k is greater than or equal to 4 and less than or equal to the digit number of the user identification card number;
s2122, performing MD5 hash operation on the number of the selected user identification card number to obtain an MD5 hash value, wherein the method for obtaining the MD5 hash value comprises the following steps:
Υ(p k′ p k′+1 p k′+2 …p k′+k )=MD5(p k′ p k′+1 p k′+2 …p k′+k ),
wherein p is 1 p 2 p 3 …p K Representing an identity card number;
p i representing an ith number in the identification card number; i is a positive integer greater than or equal to 1 and less than or equal to K; k is the total digits of the ID card number;
p k′ p k′+1 p k′+2 …p k′+k representing the slave identification card number p 1 p 2 p 3 …p K Selecting a number with a continuous digit number k; k' is greater than or equal to 1 and less than or equal toAnd is equal to K-k+1;
MD5 () means performing MD5 hash operations;
γ () represents the value of the MD5 hash obtained by performing the MD5 hash operation;
s2123, replacing the selected number with k continuous digits with the MD5 hash value to obtain a new identification card number;
s213, the obtained new ID card number is sent to a remote server terminal for verification:
if the new identification card number exists in the remote server terminal, sending a verification passing code to the detection box body;
if the new identification card number does not exist in the remote server terminal, the new identification card number is stored in a database of the remote server terminal, and a verification passing code is sent to the detection box body.
In a preferred embodiment of the present invention, the following steps are included in step S3:
s31, transmitting the data obtained by measurement and identity information corresponding to the data obtained by measurement to a remote server terminal;
s32, after the remote server terminal receives the data obtained by measurement and the identity information corresponding to the data obtained by measurement, the remote server terminal inquires the mobile phone number associated with the identity information of the remote server terminal, and the measured data of the remote server terminal is sent to the mobile intelligent handheld terminal through the mobile phone number.
In a preferred embodiment of the present invention, if the gas sensor 15 does not detect carbon monoxide, the controller sequentially transmits a conduction control command to the eighth solenoid valve and the thirteenth solenoid valve 14 to conduct the fifth connection pipe 5 and the eighth connection pipe 9 thereof, and the controller controls the gas release device to release the purge gas, and then transmits a conduction control command to the second solenoid valve 18 to discharge the exhaust gas thereof out of the detection tank 6; after the waste gas is discharged out of the detection box 6, the controller sends a closing control command to the second electromagnetic valve 18, the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve 14 so that the guide pipes of the waste gas are closed; the controller controls the gas release device to stop releasing the cleaning gas, and returns to the step S21 or S22;
S26, after the gas in the filter chamber 25 enters the combustion chamber 29, the controller sends a closing control command to the fifth electromagnetic valve 27 to convert carbon monoxide entering the combustion chamber 29 into carbon dioxide, after the conversion is finished, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve 8 and the eighth electromagnetic valve, and the controller controls the gas release device to release cleaning gas, and then sends a conduction control command to the second electromagnetic valve 18, the third electromagnetic valve, the fourth electromagnetic valve 17 and the fifth electromagnetic valve 27, and the gas converted by the combustion chamber 29 is introduced into the sedimentation chamber 3 and then is discharged out of the detection box 6; after the gas is exhausted, the controller controls the gas release device to stop releasing the cleaning gas; the controller sends closing control commands to the second solenoid valve 18, the third solenoid valve, the fourth solenoid valve, the fifth solenoid valve 27, the sixth solenoid valve, the seventh solenoid valve 7 and the eighth solenoid valve to close the pipes thereof.
In a preferred embodiment of the present invention, when the controller receives the trigger signal for cleaning and adding liquid in the filter chamber, the method comprises the following steps:
s41, the controller vibrates the pump operation T to the filter chamber installed in the filter chamber 21 1 s, the T 1 Positive number greater than or equal to 0, s is time unit seconds, T 1 Taking 10 to 25. The controller sends a conduction control command to the ninth electromagnetic valve to conduct the seventh connecting conduit, the waste liquid in the filtering chamber 21 is discharged out of the filtering chamber 21, and after the waste liquid in the filtering chamber 21 is discharged out of the filtering chamber 21, the controller sends stop information to the vibration pump of the filtering chamber and sends a closing control command to the ninth electromagnetic valve;
s42, after the vibration pump of the filtering chamber stops working and the seventh connecting conduit 24 is closed, the controller sends a conduction control command to the eleventh electromagnetic valve to conduct the eleventh connecting conduit, and liquid is added into the filtering chamber through the liquid inlet of the filtering chamber; after the liquid adding is completed, the controller sends a closing control command to an eleventh electromagnetic valve to close the guide pipe;
when the controller receives the cleaning and liquid adding trigger signal of the sedimentation chamber, the method comprises the following steps:
s43, the controller is mounted to the deviceSettling chamber vibration pump operation T in settling chamber 3 2 s, the T 2 Positive number greater than or equal to 0, s is time unit seconds, T 2 Taking 12-22. The controller sends a conduction control command to a tenth electromagnetic valve, so that a ninth connecting conduit is conducted, waste liquid in a sedimentation chamber 3 is discharged out of the sedimentation chamber 3, and after the waste liquid in the sedimentation chamber 3 is discharged out of the sedimentation chamber 3, the controller sends stop work information to a sedimentation chamber vibration pump and sends a closing control command to the tenth electromagnetic valve;
S44, after the vibration pump of the sedimentation chamber stops working and the ninth connecting conduit 28 is closed, the controller sends a conduction control command to the twelfth electromagnetic valve to conduct the tenth connecting conduit 2, and liquid is added into the sedimentation chamber through the liquid inlet of the sedimentation chamber; after the liquid adding is completed, the controller sends a closing control command to the twelfth electromagnetic valve to close the guide pipe.
In a preferred embodiment of the present invention, the step S32 further includes restoring the mobile phone number obtained by the query of the remote server terminal, where the steps include:
s321, acquiring a non-digital continuous code in a mobile phone number; the non-digital continuous code is one or any combination of A-J and a-J;
s322, mapping the obtained continuous codes to obtain MD5 hash values; the mapping relation is shown in table 1;
the relation between the continuous code and the MD5 hash value as in Table 1
S323, inquiring the obtained MD5 hash value to obtain a digital code of the MD5 hash value;
s324, replacing the continuous codes with the obtained digital codes to obtain the restored mobile phone numbers.
In this embodiment, the remote server terminal performs the following operations on the acquired mobile phone number:
the first step: selecting the continuous digit of the mobile phone number as b, namely a digital code; b is greater than or equal to 4 and less than or equal to the number of digits of the mobile phone;
Secondly, performing MD5 hash operation on the number of the selected mobile phone number to obtain an MD5 hash value, wherein the method for obtaining the MD5 hash value comprises the following steps:
ξ(C b′ C b′+1 C b′+2 …C b′+b )=MD5(C b′ C b′+1 C b′+2 …C b′+b ),
wherein C is 1 C 2 C 3 …C B Representing the number of the mobile phone;
C j representing the j-th number in the mobile phone number; j is a positive integer greater than or equal to 1 and less than or equal to B; b is the total digits of the ID card number;
C b′ C b′+1 C b′+2 …C b′+b representing the slave ID card number C 1 C 2 C 3 …C B Selecting a number with a continuous digit number b; b' is greater than or equal to 1 and less than or equal to B-b+1;
MD5 () means performing MD5 hash operations;
ζ () represents the MD5 hash value obtained by performing the MD5 hash operation;
thirdly, associating the MD5 hash value with the digital code, and inquiring through the MD5 hash value to obtain the digital code; converting the MD5 hash value obtained by the method into decimal, obtaining a decimal MD5 hash value, and mapping the decimal MD5 hash value to obtain a continuous code; the mapping relation is shown in table 2;
table 2 relation between continuous codes and MD5 hash values
And fourthly, replacing the digital codes with continuous codes to obtain the safe mobile phone numbers.
The invention also discloses a working system of the diabetes high risk group case data remote screening and extracting working method based on medical anti-fusion, as shown in fig. 2, the working system comprises a detection box body 6, wherein a generation chamber mounting seat for fixedly mounting a generation chamber 21, a filter chamber mounting seat for fixedly mounting a filter chamber 25, a combustion chamber mounting seat for fixedly mounting a combustion chamber 29 and a sedimentation chamber mounting seat for fixedly mounting a sedimentation chamber 3 are arranged in the detection box body 6; the generating chamber 21 is fixedly arranged on a generating chamber mounting seat, the filtering chamber 25 is fixedly arranged on a filtering chamber mounting seat, the combustion chamber 29 is fixedly arranged on a combustion chamber mounting seat, and the sedimentation chamber 3 is fixedly arranged on a sedimentation chamber mounting seat; in the present embodiment, the generating chamber 21 is used to convert acetone entering the generating chamber 21 into carbon monoxide, the combustion chamber 29 is used to convert carbon monoxide entering the combustion chamber 29 into carbon dioxide, and this technology belongs to the prior art and will not be described here. The solution in the filtering chamber 25 is barium chloride or calcium chloride saturated solution, absorbs carbon dioxide gas exhaled by a user, prevents errors, and the solution in the precipitating chamber 3 can also be barium chloride or calcium chloride saturated solution, absorbs carbon dioxide gas generated by the combustion chamber 29, and is convenient for calculation.
The generating chamber 21 comprises a generating chamber air inlet and a generating chamber air outlet, the filtering chamber 25 comprises a filtering chamber air inlet and a filtering chamber air outlet, the combustion chamber 29 comprises a combustion chamber air inlet and a combustion chamber air outlet, and the sedimentation chamber 3 comprises a sedimentation chamber air inlet and a sedimentation chamber air outlet;
further comprises a first connecting duct 13, a second connecting duct 16, a third connecting duct 26, a fourth connecting duct 7 and a fifth connecting duct 5;
a first end of the first connecting conduit 13 is connected with a generating chamber air inlet of the generating chamber 21, a second end of the first connecting conduit 13 is connected with the air inlet mask 10, and an induction sensor for inducing whether the air inlet mask 10 is jointed or not is arranged at a jointing part of the air inlet mask 10; the air inlet mask 10 is placed on an air inlet mask support frame 11 arranged on the detection box body 6;
the first end of the second connecting conduit 16 is connected with the generating chamber air outlet of the generating chamber 21, the second end of the second connecting conduit 16 is connected with the filtering chamber air inlet of the filtering chamber 25, the filtering chamber air inlet pipe of the filtering chamber 25 extends to be far from the bottom of the filtering chamber 25 by Xmm, X is more than 0 and less than the liquid level of the filtering chamber 25, and mm represents the length unit millimeter; preferably, X is 15 to 35. A gas sensor 15 for sensing whether the generation chamber 21 generates carbon monoxide is provided in the second connection pipe 16;
The first end of the third connecting conduit 26 is connected with the air outlet of the filtering chamber 25, and the second end of the third connecting conduit 26 is connected with the air inlet of the combustion chamber 29; a first pressure sensor for measuring the weight increase of the filter chamber is arranged between the filter chamber 25 and the filter chamber mounting seat;
the first end of the fourth connecting conduit 7 is connected with a combustion chamber air outlet of the combustion chamber 29, the second end of the fourth connecting conduit 7 is connected with a sedimentation chamber air inlet of the sedimentation chamber 3, a sedimentation chamber air inlet pipe of the sedimentation chamber 3 extends to a position which is far from the bottom Ymm of the sedimentation chamber 3, Y is more than 0 and less than the liquid level height of the sedimentation chamber 3, and mm represents the length unit millimeter; preferably, Y is 18 to 35.
The first end of the fifth connecting conduit 5 is connected with the sedimentation chamber air outlet of the sedimentation chamber 3, and the second end of the fifth connecting conduit 5 is connected with the detection box air outlet 4 of the detection box 6; a second pressure sensor for measuring the weight increase of the sedimentation chamber is arranged between the sedimentation chamber 3 and the sedimentation chamber mounting seat;
the PCB circuit board is fixedly arranged on the PCB circuit board mounting seat, a controller, a network data transmission module and an ID reading module are arranged on the PCB circuit board, the network data transmission end of the network data transmission module is connected with the network data transmission end of the controller, the data reading output end of the ID reading module is connected with the data reading input end of the controller, the sensing data output end of the sensing sensor is connected with the sensing data input end of the controller, the pressure data output end of the first pressure sensor is connected with the pressure data first input end of the controller, the pressure data output end of the second pressure sensor is connected with the pressure data second input end of the controller, and the gas-sensitive data output end of the gas-sensitive sensor 15 is connected with the gas-sensitive data input end of the controller; the touch display end of the controller is connected with the touch display end of the touch display screen arranged on the detection box body 6. In this embodiment, the network data transmission module includes a network data wireless transmission module or/and a network data wired transmission module, where a network data wireless transmission end of the network data wireless transmission module is connected to a network data wireless transmission end of the controller, and a network data wired transmission end of the network data wired transmission module is connected to a network data wired transmission end of the controller; the network data wireless transmission module comprises one or any combination of a network data wireless 3G transmission module, a network data wireless 4G transmission module, a network data wireless 5G transmission module and a network data wireless WiFi transmission module; the network data wireless 3G transmission end of the network data wireless 3G transmission module is connected with the network data wireless 3G transmission end of the controller, the network data wireless 4G transmission end of the network data wireless 4G transmission module is connected with the network data wireless 4G transmission end of the controller, the network data wireless 5G transmission end of the network data wireless 5G transmission module is connected with the network data wireless 5G transmission end of the controller, and the network data wireless WiFi transmission end of the network data wireless WiFi transmission module is connected with the network data wireless WiFi transmission end of the controller; the network wired transmission module comprises a network data wired hundred-mega transmission module and/or a network data wired giga transmission module, and a network data wired hundred-mega transmission end of the network data wired hundred-mega transmission module is connected with a network data wired hundred-mega transmission end of the controller; the network data wired gigabit transmission end of the network data wired gigabit transmission module is connected with the network data wired gigabit transmission end of the controller.
In a preferred embodiment of the present invention, one or any combination of the sixth connecting duct 12, the seventh connecting duct 24, the eighth connecting duct 9, the ninth connecting duct 28, the tenth connecting duct 2, the eleventh connecting duct; and the filter chamber 25 further comprises a filter chamber drain outlet and a filter chamber liquid inlet, and the sedimentation chamber 3 further comprises a sedimentation chamber drain outlet and a sedimentation chamber liquid inlet 1;
the first end of the sixth connecting duct 12 is connected to a gas releasing device for releasing the purge gas, and the purge gas released by the gas releasing device is not limited to nitrogen or helium, and may be selected according to actual requirements. The second end of the sixth connecting conduit 12 is connected to the first connecting conduit 13; the release gas control end of the gas release device is connected with the gas release control end of the controller;
the first end of the seventh connecting conduit 24 is connected with a sewage outlet of a filtering chamber 25, and the second end of the seventh connecting conduit 24 is connected with a waste liquid inlet of a waste liquid collecting box 22 arranged on the detection box body 6;
the first end of the eighth connecting duct 9 is connected to the second connecting duct 16, and the second end of the eighth connecting duct 9 is connected to the fifth connecting duct 5;
a first end of a ninth connecting conduit 28 is connected with a sedimentation chamber drain outlet of the sedimentation chamber 3, and a second end of the ninth connecting conduit 28 is connected with a waste liquid inlet of a waste liquid collecting box 22 arranged on the detection box body 6;
The first end of the tenth connecting conduit 2 is connected with a sedimentation chamber liquid inlet of the sedimentation chamber 3, a sedimentation chamber liquid inlet pipe of the sedimentation chamber 3 extends to a distance from the bottom Zmm of the sedimentation chamber 3, Z is a positive number larger than 0, and mm represents length unit millimeter; preferably, Z is 15 to 40. The second end of the tenth connecting conduit 2 is connected with a detection box sedimentation liquid inlet 1 of a detection box 6;
the first end of the eleventh connecting conduit is connected with the liquid inlet of the filtering chamber 25, the liquid inlet pipe of the filtering chamber 25 extends to a distance from the bottom Mmm of the filtering chamber 25, M is a positive number greater than 0, and mm represents length unit millimeter; preferably, M is 20 to 30. The second end of the eleventh connecting conduit is connected with the filtering liquid inlet of the detection box body 6.
In a preferred embodiment of the present invention, one or any combination of the first solenoid valve, the second solenoid valve 18, the third solenoid valve, the fourth solenoid valve 17, the fifth solenoid valve 27, the sixth solenoid valve, the seventh solenoid valve 8, the eighth solenoid valve, the ninth solenoid valve, the tenth solenoid valve, the eleventh solenoid valve, the twelfth solenoid valve, the thirteenth solenoid valve 14;
the first electromagnetic valve is arranged at the air inlet of the air inlet mask 10 and is used for closing and conducting the air inlet of the air inlet mask 10, and the control end of the first electromagnetic valve is connected with the first control end of the electromagnetic valve of the controller;
The second electromagnetic valve 18 is arranged at a generating chamber air inlet of the generating chamber 21 and is used for closing and conducting the generating chamber air inlet of the generating chamber 21, and the control end of the second electromagnetic valve 18 is connected with the second control end of the electromagnetic valve of the controller;
the third electromagnetic valve is arranged at the generating chamber air outlet of the generating chamber 21 and is used for closing and conducting the generating chamber air outlet of the generating chamber 21, and the control end of the third electromagnetic valve is connected with the third control end of the electromagnetic valve of the controller;
the fourth electromagnetic valve 17 is arranged at the extension end of the air inlet pipe of the filter chamber 25 and is used for closing and conducting the extension end of the air inlet pipe of the filter chamber 25, and the control end of the fourth electromagnetic valve 17 is connected with the fourth control end of the electromagnetic valve of the controller;
the fifth electromagnetic valve 27 is arranged at a combustion chamber air inlet of the combustion chamber 29 and is used for closing and conducting the combustion chamber air inlet of the combustion chamber 29, and the control end of the fifth electromagnetic valve 27 is connected with the fifth control end of the electromagnetic valve of the controller;
the sixth electromagnetic valve is arranged at the combustion chamber air outlet of the combustion chamber 29 and is used for closing and conducting the combustion chamber air outlet of the combustion chamber 29, and the control end of the sixth electromagnetic valve is connected with the six control end of the electromagnetic valve of the controller;
the seventh electromagnetic valve 8 is arranged at the extension end of the sedimentation chamber air inlet pipe of the sedimentation chamber 3 and is used for closing and conducting the extension end of the sedimentation chamber air inlet pipe of the sedimentation chamber 3, and the control end of the seventh electromagnetic valve 8 is connected with the seventh control end of the electromagnetic valve of the controller;
The eighth electromagnetic valve is arranged at the detection box body air outlet 4 of the detection box body 6 and is used for closing and conducting the detection box body air outlet 4 of the detection box body 6, and the control end of the eighth electromagnetic valve is connected with the eighth control end of the electromagnetic valve of the controller;
the ninth electromagnetic valve is arranged at the filter chamber drain outlet of the filter chamber 25 and is used for closing and conducting the filter chamber drain outlet of the filter chamber 25, and the control end of the ninth electromagnetic valve is connected with the ninth control end of the electromagnetic valve of the controller;
the tenth electromagnetic valve is arranged at the drain outlet of the settling chamber 3 and is used for closing and conducting the drain outlet of the settling chamber 3, and the control end of the tenth electromagnetic valve is connected with the tenth control end of the electromagnetic valve of the controller;
the eleventh electromagnetic valve is provided with a detection box body filtering liquid inlet of the detection box body 6 and is used for closing and conducting the detection box body filtering liquid inlet of the detection box body 6, and the control end of the eleventh electromagnetic valve is connected with the eleventh control end of the electromagnetic valve of the controller;
the twelfth electromagnetic valve is arranged at a detection box sedimentation liquid inlet of the detection box 6 and is used for closing and conducting the detection box sedimentation liquid inlet 1 of the detection box 6, and the control end of the twelfth electromagnetic valve is connected with the twelfth control end of the electromagnetic valve of the controller;
The thirteenth electromagnetic valve 14 is disposed at the first end of the eighth connecting conduit 9, and is used for closing and conducting the first end of the eighth connecting conduit 9, and the control end of the thirteenth electromagnetic valve 14 is connected with the thirteenth control end of the electromagnetic valve of the controller. In the present embodiment, it is preferable that an exhaust pump is provided in the fifth connection pipe so as to discharge the gas in the generation chamber 21 and the deposition chamber 3 out of the generation chamber 21 and the deposition chamber 3.
While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the invention, the scope of which is defined by the claims and their equivalents.
Claims (9)
1. The remote screening and extracting working method for the diabetes high risk group case data based on medical anti-fusion is characterized by comprising a detection box body, wherein a generation chamber installation seat for fixedly installing a generation chamber, a filter chamber installation seat for fixedly installing a filter chamber, a combustion chamber installation seat for fixedly installing a combustion chamber and a sedimentation chamber installation seat for fixedly installing a sedimentation chamber are arranged in the detection box body; the generation chamber is fixedly arranged on the generation chamber mounting seat, the filter chamber is fixedly arranged on the filter chamber mounting seat, the combustion chamber is fixedly arranged on the combustion chamber mounting seat, and the sedimentation chamber is fixedly arranged on the sedimentation chamber mounting seat;
The generation chamber is used for converting the acetone entering the generation chamber into carbon monoxide;
the filter chamber is used for absorbing carbon dioxide gas exhaled by a user;
the combustion chamber is used for converting carbon monoxide entering the combustion chamber into carbon dioxide;
the sedimentation chamber is used for absorbing carbon dioxide gas generated by the combustion chamber;
the generating chamber comprises a generating chamber air inlet and a generating chamber air outlet, the filtering chamber comprises a filtering chamber air inlet and a filtering chamber air outlet, the combustion chamber comprises a combustion chamber air inlet and a combustion chamber air outlet, and the sedimentation chamber comprises a sedimentation chamber air inlet and a sedimentation chamber air outlet;
the device also comprises a first connecting conduit, a second connecting conduit, a third connecting conduit, a fourth connecting conduit and a fifth connecting conduit;
the first end of the first connecting conduit is connected with a generating chamber air inlet of the generating chamber, the second end of the first connecting conduit is connected with an air inlet mask, and an induction sensor for inducing whether the air inlet mask is jointed with the air inlet mask to exhale is arranged at the joint part of the air inlet mask; the air inlet mask is placed on an air inlet mask support frame arranged on the detection box body;
the first end of the second connecting conduit is connected with the generating chamber air outlet of the generating chamber, the second end of the second connecting conduit is connected with the filtering chamber air inlet of the filtering chamber, the filtering chamber air inlet pipe of the filtering chamber extends to be an Xmm distance from the bottom of the filtering chamber, X is more than 0 and less than the liquid level of the filtering chamber, and a gas sensor for sensing whether the generating chamber generates carbon monoxide is arranged in the second connecting conduit;
The first end of the third connecting conduit is connected with the air outlet of the filtering chamber, and the second end of the third connecting conduit is connected with the air inlet of the combustion chamber; a first pressure sensor for measuring the weight increase of the filter chamber is arranged between the filter chamber and the filter chamber mounting seat;
the first end of the fourth connecting conduit is connected with a combustion chamber air outlet of the combustion chamber, the second end of the fourth connecting conduit is connected with a sedimentation chamber air inlet of the sedimentation chamber, a sedimentation chamber air inlet pipe of the sedimentation chamber extends to a distance from the sedimentation chamber bottom Ymm, and Y is more than 0 and less than the liquid level of the sedimentation chamber;
the first end of the fifth connecting conduit is connected with the air outlet of the sedimentation chamber, and the second end of the fifth connecting conduit is connected with the air outlet of the detection box body; a second pressure sensor for measuring the weight increase of the sedimentation chamber is arranged between the sedimentation chamber and the sedimentation chamber mounting seat;
the PCB circuit board is fixedly arranged on the PCB circuit board mounting seat, a controller, a network data transmission module and an ID reading module are arranged on the PCB circuit board, the network data transmission end of the network data transmission module is connected with the network data transmission end of the controller, the data reading output end of the ID reading module is connected with the data reading input end of the controller, the sensing data output end of the sensing sensor is connected with the sensing data input end of the controller, the pressure data output end of the first pressure sensor is connected with the pressure data first input end of the controller, the pressure data output end of the second pressure sensor is connected with the pressure data second input end of the controller, and the gas-sensitive data output end of the gas-sensitive sensor is connected with the gas-sensitive data input end of the controller; the touch display end of the controller is connected with the touch display end of the touch display screen arranged on the detection box body, and the working method comprises the following steps:
S1, initializing a system;
s2, acquiring measurement data of a user to be measured;
and S3, sending the measurement data in the step S2 to a remote server terminal.
2. The medical defence fusion-based working method for remotely screening and extracting case data of high risk group of diabetes mellitus according to claim 1, wherein the step S1 comprises the following steps:
s11, detecting whether the weight increment of the filter chamber or/and the weight increment of the sedimentation chamber is greater than or equal to a preset weight increment threshold value of the filter chamber and a preset weight increment threshold value of the sedimentation chamber corresponding to the weight increment threshold value of the filter chamber or/and the weight increment threshold value of the sedimentation chamber:
if the weight increase of the filter chamber is greater than or equal to the preset weight increase threshold of the filter chamber, a warning is sent out, and the filter chamber solution is added into the filter chamber; the filter chamber solution is barium chloride or calcium chloride saturated solution;
if the weight gain of the sedimentation chamber is larger than or equal to the preset weight gain threshold value of the sedimentation chamber, a warning is sent out, and the sedimentation chamber solution is added into the sedimentation chamber; the solution in the precipitation chamber is saturated solution of barium chloride or calcium chloride;
otherwise, executing the next step;
s12, the controller controls the gas release device to release the cleaning gas; the controller sequentially and respectively sends a conduction control command to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve according to the sequence; the closed pipeline is conducted;
S13, removing impurity gases in the generation chamber, the filter chamber, the combustion chamber and the sedimentation chamber by the gas to be cleaned; the controller respectively sends a closing control signal to the seventh electromagnetic valve and the fourth electromagnetic valve, and then respectively sends closing control commands to the second electromagnetic valve, the third electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve and the eighth electromagnetic valve; after the second electromagnetic valve seals the pipeline, the controller controls the gas release device to stop releasing the cleaning gas;
s14, the controller collects the weight of the filter chamber and the weight of the sedimentation chamber at the moment as the initial metering weight of the filter chamber and the initial metering weight of the sedimentation chamber respectively.
3. The medical defence fusion-based working method for remotely screening and extracting case data of high risk group of diabetes mellitus according to claim 1, wherein the step S2 comprises the following steps:
s21, acquiring identity information of a user to be tested; after the identity information of the user to be detected is obtained, executing the next step;
s22, if the controller detects that the induction sensor sends out an induction signal, the controller respectively sends out a conduction control command to the first electromagnetic valve and the second electromagnetic valve to conduct the closed pipeline; introducing the gas exhaled by the user to be tested into a generation chamber;
S23, if the controller does not detect that the induction sensor sends out an induction signal, the controller respectively sends out a closing control command to the first electromagnetic valve to close the pipeline; the controller controls the gas release device to release the cleaning gas; t is t 1 After s time, t is 1 S is a positive number greater than 0, s is a time unit of seconds, and the controller controls the gas release device to stop releasing the cleaning gas;
s24, after the gas in the generation chamber reacts, the controller sends a conduction control command to the third electromagnetic valve to conduct the conduit;
s25, if the gas sensor does not detect carbon monoxide, the controller sequentially sends a conduction control command to the eighth electromagnetic valve and the thirteenth electromagnetic valve to conduct the fifth connecting conduit and the eighth connecting conduit, and exhaust gas of the fifth connecting conduit and the eighth connecting conduit is discharged out of the detection box body; after the waste gas is discharged out of the detection box body, the controller sends a closing control command to the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve to close the guide pipe; returning to step S21 or S22;
if the gas sensor detects carbon monoxide, the controller sends a conduction control command to the fourth electromagnetic valve and the fifth electromagnetic valve, and the gas exhaled by a user is converted into carbon monoxide gas to be introduced into the filter chamber through the generating chamber of the controller, and then enters the combustion chamber;
S26, after the gas in the filter chamber enters the combustion chamber, the controller sends a closed control command to the fifth electromagnetic valve to convert carbon monoxide entering the combustion chamber into carbon dioxide, after the conversion is completed, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve, and the gas after the conversion of the combustion chamber is introduced into the sedimentation chamber and then discharged out of the detection box body; after the gas is exhausted, the controller sends a closing control command to the eighth electromagnetic valve to close the pipeline;
s27, calculating the change amount of the sedimentation chamber:
Q=Q 1 -Q 0 ,
wherein Q represents the variation of the sedimentation chamber;
Q 1 indicating the weight detected by the second pressure sensor after the gas enters the settling chamber;
Q 0 indicating the weight of the gas detected by the second pressure sensor before it enters the settling chamber.
4. The medical defence fusion-based remote screening and extracting working method for the case data of the high risk group of diabetes mellitus, according to claim 3, wherein the step S21 is characterized by comprising the following steps:
s211, if the controller receives the work trigger signal of the ID reading module, the controller sends a work control signal to the ID reading module, and the ID reading module acquires the ID card information of the ID card, wherein the ID card comprises one or any combination of an identity card, a social security medical card and a bank card; the ID card information comprises a user ID card number;
S212, carrying out data processing on the user ID card number;
s213, the obtained new ID card number is sent to a remote server terminal for verification:
if the new identification card number exists in the remote server terminal, sending a verification passing code to the detection box body;
if the new identification card number does not exist in the remote server terminal, the new identification card number is stored in a database of the remote server terminal, and a verification passing code is sent to the detection box body.
5. The medical defence fusion-based working method for remotely screening and extracting case data of high risk group of diabetes mellitus according to claim 1, wherein the step S3 comprises the following steps:
s31, transmitting the data obtained by measurement and identity information corresponding to the data obtained by measurement to a remote server terminal;
s32, after the remote server terminal receives the data obtained by measurement and the identity information corresponding to the data obtained by measurement, the remote server terminal inquires the mobile phone number associated with the identity information of the remote server terminal, and the measured data of the remote server terminal is sent to the mobile intelligent handheld terminal through the mobile phone number.
6. The medical anti-fusion based remote screening and extracting working method for the case data of the diabetes mellitus high risk group according to claim 3, wherein in the step S25, if the gas sensor does not detect carbon monoxide, the controller sequentially sends a conduction control command to the eighth electromagnetic valve and the thirteenth electromagnetic valve to conduct the fifth connecting conduit and the eighth connecting conduit, the controller controls the gas release device to release cleaning gas, and then sends the conduction control command to the second electromagnetic valve to discharge waste gas of the second electromagnetic valve out of the detection box; after the waste gas is discharged out of the detection box body, the controller sends a closing control command to the second electromagnetic valve, the third electromagnetic valve, the eighth electromagnetic valve and the thirteenth electromagnetic valve so that the guide pipe of the waste gas is closed; the controller controls the gas release means to stop releasing the purge gas, and returns to step S21 or S22.
7. The remote screening and extracting working method for the diabetes high risk group case data based on medical anti-fusion according to claim 3, wherein in the step S26, after the gas in the filtering chamber enters the combustion chamber, the controller sends a closed control command to the fifth electromagnetic valve to convert carbon monoxide entering the combustion chamber into carbon dioxide, after the conversion is completed, the controller sends a conduction control command to the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve, and the controller controls the gas release device to release cleaning gas, and then sends a conduction control command to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve, and the gas after the conversion of the combustion chamber is introduced into the settling chamber and then is discharged out of the detection box; after the gas is exhausted, the controller controls the gas release device to stop releasing the cleaning gas; the controller sends closing control commands to the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve, the seventh electromagnetic valve and the eighth electromagnetic valve to close the pipeline.
8. The medical anti-fusion based remote screening and extracting working method for case data of high risk group of diabetes mellitus, according to claim 1, wherein when a controller receives a filter chamber cleaning and liquid adding trigger signal, the method comprises the following steps:
S41, the controller vibrates the pump operation T to the filter chamber installed in the filter chamber 1 s, the T 1 When s is a positive number greater than or equal to 0, and s is a time unit second, the controller sends a conduction control command to the ninth electromagnetic valve to conduct the seventh connecting conduit, the waste liquid in the filter chamber is discharged out of the filter chamber, after the waste liquid in the filter chamber is discharged out of the filter chamber, the controller sends stop information to the vibration pump of the filter chamber, and sends a seal to the ninth electromagnetic valveClosing the control command;
s42, after the vibration pump of the filtering chamber stops working and the seventh connecting conduit is closed, the controller sends a conduction control command to the eleventh electromagnetic valve to conduct the eleventh connecting conduit, and liquid is added into the filtering chamber through the liquid inlet of the filtering chamber; after the liquid adding is completed, the controller sends a closing control command to the eleventh electromagnetic valve to close the conduit.
9. The medical anti-fusion based remote screening and extracting working method for case data of high-risk diabetes mellitus group according to claim 1, wherein when a controller receives a cleaning and liquid adding trigger signal of a settling chamber, the method comprises the following steps:
s43, the controller operates the vibration pump T of the settling chamber installed in the settling chamber 2 s, the T 2 S is a positive number greater than or equal to 0, s is a time unit second, the controller sends a conduction control command to a tenth electromagnetic valve to conduct a ninth connecting conduit, waste liquid in a sedimentation chamber is discharged out of the sedimentation chamber, after the waste liquid in the sedimentation chamber is discharged out of the sedimentation chamber, the controller sends stop information to a sedimentation chamber vibration pump, and sends a closing control command to the tenth electromagnetic valve;
s44, after the vibration pump of the sedimentation chamber stops working and the ninth connecting conduit is closed, the controller sends a conduction control command to the twelfth electromagnetic valve to conduct the tenth connecting conduit, and liquid is added into the sedimentation chamber through the liquid inlet of the sedimentation chamber; after the liquid adding is completed, the controller sends a closing control command to the twelfth electromagnetic valve to close the guide pipe.
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