CN114814140A - Method and system capable of realizing automatic matching of water sample and water sample analysis result - Google Patents

Abstract

The invention discloses a method and a system capable of realizing automatic matching of a water sample and a water sample analysis result, wherein the step S100 is as follows: the matching system automatically acquires sampling geographic coordinate information and sampling time information corresponding to the water sample; step S200: the matching system is used for solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility; step S300: the matching system judges a plurality of associated building facilities of a water quality influence path between the sampling point and the matching system; step S400: acquiring an index range of water quality index influence of a plurality of associated building facilities on a sampling point; generating an index sequence to be analyzed based on the index range; step S500: editing the content of the near field communication label corresponding to each water quality sampling bottle; step S600: generating a corresponding water quality analysis demand based on each tag id; and automatically matching the water sample under each water quality analysis requirement with the water sample analysis result.

Description

Method and system capable of realizing automatic matching of water sample and water sample analysis result

Technical Field

The invention relates to the technical field of water sample detection automation, in particular to a method and a system capable of realizing automatic matching of a water sample and a water sample analysis result.

Background

Water samples need to be collected on site in daily work of water treatment site operation and maintenance engineers, then the water samples are sent to a designated water treatment analysis laboratory for water quality analysis, and the obtained water quality analysis results and information such as physical positions of water sample collection points, water sample collection time, indexes needing analysis, water sample collection personnel, laboratory analysts and the like generate analysis reports and send the analysis reports to the operation and maintenance engineers, so that the operation and maintenance engineers can further judge the site water quality conditions and take corresponding measures to improve the treatment process.

Conventionally, information such as a field name, a sampling time, an index to be analyzed, and the like is written on a note paper and then attached to a sampling bottle, which generally causes the following problems: the information is incomplete; the notepaper of the water sample is lost in the transportation process; the notepaper is polluted and the content of the water sample cannot be identified in the transportation process; the operation and maintenance engineer is sloppy in handwriting, and the laboratory staff cannot recognize the label content; laboratory personnel need to manually input the label content into laboratory equipment again, the labor is repeated, and the error probability is increased; if the above problems occur, the final detection result cannot be correctly matched with the original water sample, and the quality and speed of the field water quality treatment are greatly influenced.

Disclosure of Invention

The invention aims to provide a method and a system capable of realizing automatic matching of a water sample and a water sample analysis result, so as to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: a method for automatically matching a water sample with an analysis result of the water sample comprises the following steps:

step S100: a water treatment operation and maintenance engineer collects a water sample by using a water sampling bottle in a sampling site and then correspondingly creates a water sample in a matching system; the water quality sampling bottle can be made of plastic or glass so as to meet different water quality analysis requirements; the matching system automatically acquires sampling geographic coordinate information and sampling time information corresponding to the water sample;

step S200: the matching system takes the geographic coordinates of the sampling points as a reference, and takes all the building facilities in the sampling environment which meets the distance threshold value between the geographic coordinates of the sampling points as the range of the target facilities; the matching system is used for solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility;

step S300: the matching system judges a plurality of associated building facilities of a water quality influence path between each building facility and a sampling point based on a water discharge diffusion angle and a water discharge diffusion area of each building facility in a target facility range and a range area position of the sampling site corresponding to the sampling point;

step S400: acquiring an index range of water quality index influence of a plurality of associated building facilities on a sampling point; generating an index sequence to be analyzed based on the index range; pushing the index sequence to be analyzed to a water treatment operation and maintenance engineer; the water treatment operation and maintenance engineer completes the final selection and editing of the index to be analyzed and the selection of a water quality analysis laboratory based on the index sequence to be analyzed;

step S500: setting a near field communication tag with a unique tag id for each water quality sampling bottle; one water quality sampling bottle corresponds to one water sample; editing the content of the near field communication label corresponding to each water quality sampling bottle; the content of the near field communication label corresponding to each water quality sampling bottle comprises the following components: sampling geographic coordinate information, sampling time information, name information of water sample sampling points, index sequence information to be analyzed, selected water quality analysis laboratory information and contact information of a water treatment operation and maintenance engineer which are finally selected and edited by the water treatment operation and maintenance engineer corresponding to the water sample;

step S600: generating a corresponding water quality analysis demand based on each tag id; and automatically matching the water sample under each water quality analysis requirement with the water sample analysis result.

Further, the step S200 of determining the water quality influence path existing between the sampling site and the sampling site based on the sampling point geographic coordinate, the sampling time and the sampling point geographic feature includes:

step S201: taking the geographic coordinates of the sampling points as a reference, taking all the building facilities in the sampling environment meeting the distance threshold value between the geographic coordinates of the sampling points as a target facility range, and acquiring water discharge path information of all the building facilities in the target facility range; recording the water discharge path of the ith building facility in the range of the target facility

Wherein

Indicating the location of a water discharge source of the ith building facility;

represents by

A collection formed by a plurality of areas through which the discharged water flow passes; wherein, w ₁ 、w ₂ 、…、w _n Represents from

The 1 st, 2 nd, … th and n th areas where the discharged water flow passes through;

step S202: respectively to be provided with

In each region and

between them several directed edge connecting lines are constructed, the direction directions are respectively

Point of direction w ₁ 、w ₂ 、…、w _n In the form of

Converting a plurality of pointing connecting lines into vector line segments with directions in a two-dimensional rectangular coordinate system respectively; the two-dimensional space rectangular coordinate system is a first rectangular coordinate system; to be provided with

The position coordinates of the first rectangular coordinate system are the origin position coordinates of the first rectangular coordinate system; two vector line segments with the largest included angle are locked between the included angles of the directional vector line segments in the first rectangular coordinate system, and simultaneouslyThe maximum vector line segment angle is used as the correspondence

The angle of divergence of;

step S203: respectively representing the lengths of each vector line segment in the first rectangular coordinate system

And w ₁ 、w ₂ 、…、w _n The actual position distance between the two vector line segments is formed by connecting the tail parts of all the vector line segments

A closed diffusion region based on the diffusion angle of (a);

the process of obtaining the water quality influence path is equivalent to a process of judging that no water discharge path intersection exists between a sampling site where the sampling point is located and each facility within the range of the target facility; if the crossed water discharge areas exist, the possibility that the water discharge of the facilities influences the water quality of the sampling site is meant, then in the selection of subsequent water quality indexes, the daily work attribute information related to the facilities is considered, and the influenced indexes are taken as one of the indexes to be detected; because some water quality indexes can not be seen by human eyes, the capture analysis depending on some rules is beneficial to reducing the occurrence of the phenomenon of error and leakage during the detection of the water quality indexes.

Further, the step S300 of determining a plurality of associated building facilities having water quality influencing paths with the sampling points includes:

step S301: from

Guiding a ray at a position of bisection of the diffusion angle, and representing the direction of the ray

The overall direction of the closed diffusion region; to be provided with

The whole direction of the closed diffusion area is used as the x-axis direction in a two-dimensional rectangular space coordinate system, and the direction vertical to the x-axis direction is used as the y-axis to construct and generate a second rectangular coordinate system;

step S302: acquiring the range region position contained in the sampling current place where the sampling point is located, and performing label display on the range region position contained in the sampling current place in a second rectangular coordinate system; to pair

Capturing a superposition region between the closed diffusion region and a range position region corresponding to the sampling environment;

step S303: if it is

A superposition area exists between the closed diffusion area and a range position area corresponding to the sampling environment, a water quality influence path exists between the sampling point and the ith building facility in the target facility range, and the ith building facility in the target facility range is the associated building facility of the sampling point;

because the water flow direction discharged from one water discharge source is uneven because of the area passed by the water flow or the topography problem is prone to have diffusion phenomenon, so that the water flow direction discharged from one water discharge source is not fixed, the area passed by the discharged water flow is not fixed, and two vector line segments presenting the maximum included angle between the included angles of the vector line segments are used as two edges for limiting the diffusion angle size

Further, step S400 includes:

step S401: respectively acquiring attribute information of a plurality of associated building facilities, and acquiring various pollutant source substances existing in the associated building facilities corresponding to different attribute information based on big data; respectively obtaining affected water quality index items corresponding to various pollution source substances;

step S402: respectively collecting the affected water quality index ranges obtained from the associated building facilities; capturing repeatedly appeared influenced water quality index items in the influenced water quality index ranges corresponding to all associated building facilities; sorting various types of affected water quality index items in the affected water quality index range corresponding to all associated building facilities according to repeated occurrence times from more to less to obtain an affected water quality index sequence; the affected water quality index sequence is used as an index sequence to be analyzed and pushed to a water treatment operation engineer;

step S403: the water treatment operation and maintenance engineer completes the final selection and editing of the index to be analyzed based on the index sequence to be analyzed; the selected editing mode comprises partial selection of the index to be analyzed in the index sequence to be analyzed, full selection of the index to be analyzed in the index sequence to be analyzed, and index supplement of the index to be analyzed in the index sequence to be analyzed.

Further, step S600 includes:

step S601: the matching system submits the near field communication tag corresponding to each water sample and the id of the near field communication tag to a cloud server through a network to generate a corresponding water quality analysis requirement;

step S602: the cloud server receives the water quality analysis requirement, creates a corresponding water quality analysis task according to a near field communication tag id corresponding to the water quality analysis requirement, and informs a water quality analysis laboratory in the tag content of the water quality analysis task in a message pushing mode; laboratory analysts can check the water quality analysis task through the matching system and wait for delivery of the corresponding water quality sampling bottles;

step S600: after receiving the water quality sampling bottle, a water quality analysis laboratory worker reads the id of the near field communication tag by scanning the near field communication tag on the water quality sampling bottle, and extracts a corresponding water quality analysis task in the cloud server according to the id of the near field communication tag; laboratory personnel analyze the water sample in the water quality sampling bottle; the analysis result can be directly input into a Web page provided by a matching system or a cloud server.

Further, step S600 further includes:

step S611: when laboratory personnel analyze the water sample in the water quality sampling bottle, the matching system sets the corresponding water quality analysis task to be in the processing state, and updates and pushes the state of the water quality analysis task to a water treatment operation and maintenance engineer;

step S612: after the laboratory staff completes the analysis of the water sample in the water quality sampling bottle, the matching system sets the corresponding water quality analysis task to be in a treatment completion state, and pushes the analysis result of the water quality analysis task to a water treatment operation and maintenance engineer.

In order to better realize the method, a system capable of realizing automatic matching of the water sample and the analysis result is also provided, and the system comprises: the system comprises a water sample information acquisition module, a facility water discharge information processing module, a related building facility identification module, an index sequence to be analyzed generation module, a near field communication tag information input module and a cloud matching module;

the water sample information acquisition module is used for automatically acquiring sampling geographic coordinate information and sampling time information corresponding to a water sample;

the facility water discharge information processing module is used for receiving the data in the water sample information acquisition module and solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility;

the associated building facility identification module is used for receiving the data in the facility water discharge information processing module and judging and identifying a plurality of associated building facilities of a water quality influence path between the sampling points based on the data and the range area position of the sampling site corresponding to the sampling points;

the to-be-analyzed index sequence generation module is used for receiving the data in the associated building facility identification module, acquiring an index range of a plurality of associated building facilities influencing the water quality index of the sampling point, and generating an to-be-analyzed index sequence;

the near field communication label information input module is used for receiving data in the water sample information acquisition module, the facility water discharge information processing module, the associated building facility identification module and the to-be-analyzed index sequence generation module, and editing the content of the near field communication label corresponding to each water quality sampling bottle based on the data;

and the cloud matching module is used for receiving the data in the near field communication tag information input module and automatically matching the water sample and the water sample analysis result under each water quality analysis requirement based on the data.

Further, the facility water discharge information processing module comprises a water discharge diffusion angle calculating unit and a water discharge diffusion area calculating unit;

the water drainage spread angle calculation unit is used for receiving the data in the water sample information acquisition module and calculating the water drainage spread angle of each building facility within the range of the target facility;

and the water discharge diffusion area calculating unit is used for receiving the data in the water sample information acquiring module and the water discharge diffusion angle calculating unit and calculating the water discharge diffusion area of each building facility within the range of the target facility.

Further, the associated building facility identification module comprises a water quality influence path judgment unit and an associated building facility identification unit;

the water quality influence path judging unit is used for receiving data in the facility water discharge information processing module and judging the water quality influence path based on the water discharge diffusion angle and the water discharge diffusion area of each building facility;

and the related building facility identification unit is used for receiving the data in the water quality influence path judgment unit and identifying the related building facility based on the data.

Compared with the prior art, the invention has the following beneficial effects: the invention can solve the problems of unavoidable loss, pollution, incomplete information, incapability of identification and the like of the traditional paper label, adopts the near field communication technology to standardize the content of the label, adopts the mobile internet and the cloud computing/storing technology to simplify the operation of field personnel, and improves the integrity and the identifiability of information; the wireless positioning technology is adopted to ensure the accurate description of the position information of the water sample collection place, and the efficiency and the accuracy of the integration of the water quality analysis result and the water sample original information are greatly improved; meanwhile, the selection of the indexes to be detected of the water quality is beneficial to capturing the selection rule of the indexes to be detected through artificial intelligence, the selection reference of the indexes to be detected is provided for operation and maintenance engineers, and the condition that the water quality detection is reworked due to omission of the selective detection of a certain water quality index is reduced in the process of water quality operation and maintenance detection; thereby improving the automation degree of the whole process from sampling, analyzing and generating reports to publishing reports.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic flow chart of a method for automatically matching water samples with water sample analysis results according to the present invention;

FIG. 2 is a schematic structural diagram of a system for automatically matching water samples with water sample analysis results according to the present invention;

fig. 3 is a diagram of an embodiment of a method for automatically matching water samples with water sample analysis results according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a method for automatically matching a water sample with an analysis result of the water sample comprises the following steps:

step S100: a water treatment operation and maintenance engineer collects a water sample by using a water sampling bottle in a sampling site and then correspondingly creates a water sample in a matching system; the matching system automatically acquires sampling geographic coordinate information and sampling time information corresponding to the water sample;

step S200: the matching system takes the geographic coordinates of the sampling points as a reference, and takes all the building facilities in the sampling environment which meets the distance threshold value between the geographic coordinates of the sampling points as the range of the target facilities; the matching system is used for solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility;

wherein, the process of judging the water quality influence path existing between the sampling site and the sampling site based on the sampling point geographic coordinate and the sampling time by combining the sampling point geographic characteristic comprises the following steps:

step S201: taking the geographic coordinates of the sampling points as a reference, taking all the building facilities in the sampling environment meeting the distance threshold value between the geographic coordinates of the sampling points as a target facility range, and acquiring water discharge path information of all the building facilities in the target facility range; recording the water discharge path of the ith building facility in the range of the target facility

Wherein

Indicating the location of a water discharge source of the ith building facility;

represents by

A collection formed by a plurality of areas through which the discharged water flow passes; wherein, w ₁ 、w ₂ 、…、w _n Represents from

The 1 st, 2 nd, … th and n th areas where the discharged water flow passes through;

step S202: respectively to be provided with

In each region and

between them several directed edge connecting lines are constructed, the direction directions are respectively

Point of direction w ₁ 、w ₂ 、…、w _n In the form of

Converting a plurality of pointing connecting lines into vector line segments with directions in a two-dimensional rectangular coordinate system respectively; the two-dimensional space rectangular coordinate system is a first rectangular coordinate system; to be provided with

The position coordinates of the first rectangular coordinate system are the origin position coordinates of the first rectangular coordinate system; two vector line segments with the largest included angle are locked between the included angles of the directional vector line segments in the first rectangular coordinate system, and the included angle of the largest vector line segment is taken as the corresponding included angle

The angle of divergence of;

step S203: respectively representing the lengths of each vector line segment in the first rectangular coordinate system

And w ₁ 、w ₂ 、…、w _n The actual position distance between the two vector line segments is formed by connecting the tail parts of all the vector line segments

A closed diffusion region based on the diffusion angle of (a);

step S300: the matching system judges a plurality of associated building facilities of a water quality influence path between each building facility and a sampling point based on a water discharge diffusion angle and a water discharge diffusion area of each building facility in a target facility range and a range area position of the sampling site corresponding to the sampling point;

wherein, the process of judging that a plurality of associated building facilities with water quality influence paths exist between sampling points comprises the following steps:

step S301: from

Guiding a ray at a position of bisection of the diffusion angle, and representing the direction of the ray

The overall direction of the closed diffusion region; to be provided with

The whole direction of the closed diffusion area is used as the x-axis direction in a two-dimensional rectangular space coordinate system, and the direction vertical to the x-axis direction is used as the y-axis to construct and generate a second rectangular coordinate system;

step S302: acquiring the range region position contained in the sampling current place where the sampling point is located, and performing label display on the range region position contained in the sampling current place in a second rectangular coordinate system; to pair

Capturing a superposition region between the closed diffusion region and a range position region corresponding to the sampling environment;

step S303: if it is

A superposition area exists between the closed diffusion area and a range position area corresponding to the sampling environment, a water quality influence path exists between the sampling point and the ith building facility in the target facility range, and the ith building facility in the target facility range is the associated building facility of the sampling point;

step S400: acquiring an index range of water quality index influence of a plurality of associated building facilities on a sampling point; generating an index sequence to be analyzed based on the index range; pushing the index sequence to be analyzed to a water treatment operation and maintenance engineer; the water treatment operation and maintenance engineer completes the final selection and editing of the index to be analyzed and the selection of a water quality analysis laboratory based on the index sequence to be analyzed;

wherein, step S400 includes:

step S401: respectively acquiring attribute information of a plurality of associated building facilities, and acquiring various pollutant source substances existing in the associated building facilities corresponding to different attribute information based on big data; respectively obtaining affected water quality index items corresponding to various pollution source substances;

step S402: respectively collecting the affected water quality index ranges obtained from the associated building facilities; capturing repeatedly appeared influenced water quality index items in the influenced water quality index ranges corresponding to all associated building facilities; sorting various types of affected water quality index items in the affected water quality index range corresponding to all associated building facilities according to repeated occurrence times from more to less to obtain an affected water quality index sequence; the affected water quality index sequence is used as an index sequence to be analyzed and pushed to a water treatment operation engineer;

step S403: the water treatment operation and maintenance engineer completes the final selection and editing of the index to be analyzed based on the index sequence to be analyzed; the selected editing mode comprises the steps of partially selecting the indexes to be analyzed in the index sequence to be analyzed, fully selecting the indexes to be analyzed in the index sequence to be analyzed and supplementing the indexes to be analyzed in the index sequence to be analyzed;

step S500: setting a near field communication tag with a unique tag id for each water quality sampling bottle; one water quality sampling bottle corresponds to one water sample; editing the content of the near field communication label corresponding to each water quality sampling bottle; the content of the near field communication label corresponding to each water quality sampling bottle comprises the following components: sampling geographic coordinate information, sampling time information, name information of water sample sampling points, index sequence information to be analyzed, selected water quality analysis laboratory information and contact information of a water treatment operation and maintenance engineer which are finally selected and edited by the water treatment operation and maintenance engineer corresponding to the water sample;

step S600: generating a corresponding water quality analysis demand based on each tag id; automatically matching the water sample under each water quality analysis requirement with the water sample analysis result;

wherein, step S600 includes:

step S601: the matching system submits the near field communication tag corresponding to each water sample and the id of the near field communication tag to a cloud server through a network to generate a corresponding water quality analysis requirement;

step S602: the cloud server receives the water quality analysis requirement, creates a corresponding water quality analysis task according to a near field communication tag id corresponding to the water quality analysis requirement, and informs a water quality analysis laboratory in the tag content of the water quality analysis task in a message pushing mode; laboratory analysts can check the water quality analysis task through the matching system and wait for delivery of the corresponding water quality sampling bottles;

step S600: after receiving the water quality sampling bottle, a water quality analysis laboratory worker reads the id of the near field communication tag by scanning the near field communication tag on the water quality sampling bottle, and extracts a corresponding water quality analysis task in the cloud server according to the id of the near field communication tag; laboratory personnel analyze the water sample in the water quality sampling bottle; the analysis result can be directly input into a Web page provided by a matching system or a cloud server;

for example, as shown in fig. 3, App may correspond to a matching system;

wherein, step S600 further includes:

step S611: when laboratory personnel analyze the water sample in the water quality sampling bottle, the matching system sets the corresponding water quality analysis task to be in the processing state, and updates and pushes the state of the water quality analysis task to a water treatment operation and maintenance engineer;

step S612: after the laboratory staff completes the analysis of the water sample in the water quality sampling bottle, the matching system sets the corresponding water quality analysis task to be in a treatment completion state, and pushes the analysis result of the water quality analysis task to a water treatment operation and maintenance engineer.

In order to better realize the method, a system capable of realizing automatic matching of the water sample and the analysis result is also provided, and the system comprises: the system comprises a water sample information acquisition module, a facility water discharge information processing module, a related building facility identification module, an index sequence to be analyzed generation module, a near field communication tag information input module and a cloud matching module;

the water sample information acquisition module is used for automatically acquiring sampling geographic coordinate information and sampling time information corresponding to a water sample;

the facility water discharge information processing module is used for receiving the data in the water sample information acquisition module and solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility;

the facility water discharge information processing module comprises a water discharge diffusion angle calculating unit and a water discharge diffusion area calculating unit;

the water drainage spread angle calculation unit is used for receiving the data in the water sample information acquisition module and calculating the water drainage spread angle of each building facility within the range of the target facility;

the water discharge diffusion area solving unit is used for receiving data in the water sample information acquisition module and the water discharge diffusion angle solving unit and solving the water discharge diffusion area of each building facility within the range of the target facility;

the associated building facility identification module is used for receiving the data in the facility water discharge information processing module and judging and identifying a plurality of associated building facilities of a water quality influence path between the sampling points based on the data and the range area position of the sampling site corresponding to the sampling points;

the relevant building facility identification module comprises a water quality influence path judgment unit and a relevant building facility identification unit;

the water quality influence path judging unit is used for receiving data in the facility water discharge information processing module and judging the water quality influence path based on the water discharge diffusion angle and the water discharge diffusion area of each building facility;

the related building facility identification unit is used for receiving the data in the water quality influence path judgment unit and identifying related building facilities based on the data;

the to-be-analyzed index sequence generation module is used for receiving the data in the associated building facility identification module, acquiring an index range of a plurality of associated building facilities influencing the water quality index of the sampling point, and generating an to-be-analyzed index sequence;

the near field communication label information input module is used for receiving data in the water sample information acquisition module, the facility water discharge information processing module, the associated building facility identification module and the to-be-analyzed index sequence generation module, and editing the content of the near field communication label corresponding to each water quality sampling bottle based on the data;

and the cloud matching module is used for receiving the data in the near field communication tag information input module and automatically matching the water sample and the water sample analysis result under each water quality analysis requirement based on the data.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A method for automatically matching a water sample with an analysis result of the water sample is characterized by comprising the following steps:

step S100: a water treatment operation and maintenance engineer collects a water sample by using a water sampling bottle in a sampling site and then correspondingly creates a water sample in a matching system; the matching system automatically acquires sampling geographic coordinate information and sampling time information corresponding to the water sample;

step S200: the matching system takes the geographic coordinates of the sampling points as a reference, and takes all the building facilities in the sampling environment which meets a distance threshold value between the geographic coordinates of the sampling points and the matching system as a target facility range; the matching system is used for solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within the range of the target facility;

step S300: the matching system judges a plurality of associated building facilities of a water quality influence path between each building facility and a sampling point based on a water discharge diffusion angle and a water discharge diffusion area of each building facility in a target facility range and a range area position of the sampling site corresponding to the sampling point;

step S400: acquiring an index range of the water quality index influence of the plurality of associated building facilities on a sampling point; generating an index sequence to be analyzed based on the index range; pushing the index sequence to be analyzed to a water treatment operation and maintenance engineer; the water treatment operation and maintenance engineer completes the final selection and editing of the index to be analyzed and the selection of a water quality analysis laboratory based on the index sequence to be analyzed;

step S500: setting a near field communication tag with a unique tag id for each water quality sampling bottle; one water quality sampling bottle corresponds to one water sample; editing the content of the near field communication label corresponding to each water quality sampling bottle; the content of the near field communication label corresponding to each water quality sampling bottle comprises: sampling geographic coordinate information, sampling time information, name information of water sample sampling points, index sequence information to be analyzed, selected water quality analysis laboratory information and contact information of a water treatment operation and maintenance engineer which are finally selected and edited by the water treatment operation and maintenance engineer corresponding to the water sample;

step S600: generating a corresponding water quality analysis demand based on each tag id; and automatically matching the water sample under each water quality analysis requirement with the water sample analysis result.

2. The method according to claim 1, wherein the step S200 of determining the water quality influence path existing between the sampling site and the sampling site based on the sampling point geographic coordinates and the sampling time in combination with the sampling point geographic features comprises:

step S201: taking the geographic coordinates of the sampling points as a reference, taking all the building facilities in a sampling environment meeting a distance threshold value between the geographic coordinates of the sampling points as a target facility range, and acquiring water discharge path information of all the building facilities in the target facility range; recording the water discharge path of the ith building facility in the range of the target facility

Wherein

Indicating the location of a water discharge source of the ith building facility;

represents by

A collection formed by a plurality of areas through which the discharged water flow passes; wherein, w ₁ 、w ₂ 、…、w _n Represents from

The 1 st, 2 nd, … th and n th areas where the discharged water flow passes through;

step S202: respectively to be provided with

In each region and

between them construct several directed edgesLines, direction of which are respectively directed to

Point of direction w ₁ 、w ₂ 、…、w _n In the form of

Converting the plurality of pointing connecting lines into vector line segments with directions in a two-dimensional rectangular space coordinate system respectively; the two-dimensional space rectangular coordinate system is a first rectangular coordinate system; to be provided with

The position coordinates of the first rectangular coordinate system are the origin position coordinates of the first rectangular coordinate system; two vector line segments with the largest included angle are present between the included angles of the locking orientation quantity line segments in the first rectangular coordinate system, and the included angle of the largest vector line segment is taken as the corresponding included angle

The angle of divergence of;

step S203: respectively representing the lengths of each vector line segment in the first rectangular coordinate system

And w ₁ 、w ₂ 、…、w _n The actual position distance between the two vector line segments is formed by connecting the tail parts of all the vector line segments

Is used as a base of the diffusion angle of the closed diffusion region.

3. The method for automatically matching the analysis results of the water sample and the water sample according to claim 2, wherein the step S300 of judging the plurality of associated building facilities with the sampling points, which have the water quality influence paths, comprises the following steps:

step S301: from

Guiding a ray at a position of bisection of the diffusion angle, and representing the direction of the ray as

The overall direction of the closed diffusion region; to be provided with

The whole direction of the closed diffusion area is used as the x-axis direction in a two-dimensional rectangular space coordinate system, and a y-axis perpendicular to the x-axis direction is constructed to generate a second rectangular coordinate system;

step S302: acquiring the range region position included in the sampling current place where the sampling point is located, and performing labeling display on the range region position stomach included in the sampling current place in the second rectangular coordinate system; to pair

Capturing a superposition region between the closed diffusion region and a range position region corresponding to the sampling environment;

step S303: if it is

And determining that a water quality influence path exists between the sampling point and the ith building facility within the range of the target facility, wherein the ith building facility within the range of the target facility is the associated building facility of the sampling point.

4. The method for automatically matching the analysis results of water samples according to claim 1, wherein the step S400 comprises:

step S401: respectively acquiring attribute information of the plurality of associated building facilities, and acquiring various pollutant source substances existing in the associated building facilities corresponding to different attribute information based on big data; respectively obtaining affected water quality index items corresponding to various pollution source substances;

step S402: respectively collecting the affected water quality index ranges obtained from the associated building facilities; capturing repeatedly appeared influenced water quality index items in the influenced water quality index ranges corresponding to all associated building facilities; sorting various types of affected water quality index items in the affected water quality index range corresponding to all associated building facilities according to repeated occurrence times from more to less to obtain an affected water quality index sequence; the affected water quality index sequence is used as an index sequence to be analyzed and pushed to a water treatment operation engineer;

step S403: the water treatment operation and maintenance engineer completes the selection and editing of the final index to be analyzed based on the index sequence to be analyzed; the selected editing mode comprises partial selection of the indexes to be analyzed in the index sequence to be analyzed, full selection of the indexes to be analyzed in the index sequence to be analyzed, and index supplement of the indexes to be analyzed in the index sequence to be analyzed.

5. The method for automatically matching the analysis results of water samples according to claim 1, wherein the step S600 comprises:

step S601: the matching system submits the near field communication tag corresponding to each water sample and the id of the near field communication tag to a cloud server through a network to generate a corresponding water quality analysis requirement;

step S602: the cloud server receives the water quality analysis demand, creates a corresponding water quality analysis task according to the near field communication tag id corresponding to the water quality analysis demand, and informs a water quality analysis laboratory in tag content of the water quality analysis task in a message pushing mode; laboratory analysts can check the water quality analysis task through the matching system and wait for delivery of the corresponding water quality sampling bottles;

step S600: after receiving a water quality sampling bottle, a water quality analysis laboratory worker reads the id of the near field communication tag by scanning the near field communication tag on the water quality sampling bottle, and extracts a corresponding water quality analysis task in a cloud server according to the id of the near field communication tag; laboratory personnel analyze the water sample in the water quality sampling bottle; the analysis result can be directly input into a Web page provided by a matching system or a cloud server.

6. The method for automatically matching the analysis results of a water sample with the analysis results of the water sample according to claim 5, wherein the step S600 further comprises:

step S611: when laboratory personnel analyze the water sample in the water quality sampling bottle, the matching system sets the corresponding water quality analysis task to be in the processing state, and updates and pushes the state of the water quality analysis task to a water treatment operation and maintenance engineer;

step S612: after laboratory personnel finish to the water sample analysis in the water quality sampling bottle, matching system can set up to this time corresponding water quality analysis task and set up to handle the completion state to the analysis result of this water quality analysis task is propelling supply water treatment operation and maintenance engineer.

7. A system for automatically matching water samples with analysis results, which is applied to the method for automatically matching water samples with analysis results according to any one of claims 1 to 6, and is characterized in that the system comprises: the system comprises a water sample information acquisition module, a facility water discharge information processing module, a related building facility identification module, an index sequence to be analyzed generation module, a near field communication tag information input module and a cloud matching module;

the water sample information acquisition module is used for automatically acquiring sampling geographic coordinate information and sampling time information corresponding to the water sample;

the facility water discharge information processing module is used for receiving the data in the water sample information acquisition module and solving a water discharge diffusion angle and a water discharge diffusion area of each building facility within a target facility range;

the associated building facility identification module is used for receiving the data in the facility water discharge information processing module and judging and identifying a plurality of associated building facilities of a water quality influence path between the associated building facilities and a sampling point based on the data and the range area position of the sampling site corresponding to the sampling point;

the to-be-analyzed index sequence generation module is used for receiving the data in the associated building facility identification module, acquiring an index range of a plurality of associated building facilities influencing a water quality index of a sampling point, and generating an to-be-analyzed index sequence;

the near field communication label information input module is used for receiving data in the water sample information acquisition module, the facility water discharge information processing module, the associated building facility identification module and the index sequence generation module to be analyzed, and editing the content of the near field communication label corresponding to each water quality sampling bottle based on the data;

and the cloud matching module is used for receiving the data in the near field communication tag information input module and automatically matching the water sample and the water sample analysis result under each water quality analysis requirement based on the data.

8. The system capable of automatically matching water samples with water sample analysis results according to claim 7, wherein the facility water discharge information processing module comprises a water discharge spread angle solving unit and a water discharge spread area solving unit;

the water discharge spread angle solving unit is used for receiving the data in the water sample information acquisition module and solving the water discharge spread angle of each building facility within the range of the target facility;

and the water discharge diffusion area calculating unit is used for receiving the data in the water sample information acquiring module and the water discharge diffusion angle calculating unit and calculating the water discharge diffusion area of each building facility within the range of the target facility.

9. The system capable of automatically matching the analysis results of the water sample and the water sample according to claim 7, wherein the associated building facility identification module comprises a water quality influence path judgment unit and an associated building facility identification unit;

the water quality influence path judging unit is used for receiving the data in the facility water discharge information processing module and judging the water quality influence path based on the water discharge diffusion angle and the water discharge diffusion area of each building facility;

and the related building facility identification unit is used for receiving the data in the water quality influence path judgment unit and identifying related building facilities based on the data.

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