User account	Contact means	Fishpond mark	Container label
				Zhang three	135********	Fish pond 1	Container identification 1 two-dimensional code
Li Si	159********	Fishpond 2	2 two-dimensional code of container identification

TABLE 1

And the culture user samples the water body of the fish pond, loads the water body into a delivery inspection container corresponding to the fish pond, and delivers the water body to the service station water quality detection equipment for identification and detection. The specific flow is shown in figure 1.

When the water quality detection equipment of the service station receives the inspection container from the culture user, thestep 101 is entered, and the container identifier of the inspection container is identified.

Instep 102, the water quality detection device performs water quality detection on the water body in the inspection container. The detection categories may include nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH, dissolved oxygen, and the like.

In step 103, the water quality detection device sends the detected water quality detection data and the corresponding container identifier to the information service platform.

Instep 104, the information service platform determines the fishpond identification and the user information corresponding to the received submission identification according to the stored corresponding relationship table, and stores the received water quality detection data and the fishpond identification in a related manner, for example, in a file or an area corresponding to the fishpond identification.

Instep 105, the information service platform analyzes the water quality detection data of the fish pond. If the water quality detection data of each category exceeds the preset water quality data safety range of the corresponding category, generating an analysis result, wherein the analysis result generally comprises a judgment conclusion (such as water quality safety, water quality alarm and the like) and a corresponding mode, and the corresponding mode is optional. For example, after the concentration of nitrite in water is accumulated to 0.1mg/l, the nitrite can cause harm to fishes, shrimps and crabs cultured in the water body, the safety range of the nitrite can be set to be lower than 0.08mg/l, when the detected nitrite concentration exceeds 0.08mg/l, the conclusion is that the water quality is alarmed, and when the detected nitrite concentration exceeds 0.1mg/l, a coping-up mode is generated, namely, fishermen are informed of what measures need to be taken for corresponding treatment.

Or, in this step, the change trend of the water quality detection data in a specified time period (e.g., within one week) may be analyzed to generate an analysis result, where the analysis result at least includes a conclusion of the water quality change trend and a corresponding mode. If the conclusion of the water quality change trend can be 'water quality is deteriorated and early warning is carried out', the coping mode is generally a specific water quality treatment mode. Along with treatment, when the deteriorated water quality is improved and meets the qualified requirement, the conclusion of the water quality change trend can be 'water quality recovery', and the corresponding mode can be a suggestion for stopping the continuous improvement of the water quality so as to prevent the reverse deterioration of the water quality caused by excessive improvement.

Instep 106, the information service platform feeds back the water quality detection data and the analysis result of the corresponding fishpond to the corresponding culture user according to the determined fishpond identification and the user information.

The specific feedback mode may be: the method comprises the following steps of mobile phone short message notification, mobile phone voice notification, APP text information pushing, APP voice information pushing and APP query interface display (namely, display is carried out when a user opens APP query).

Through this embodiment for breed user in an area can share same water quality testing equipment, unified whole water quality monitoring and the management of accepting information service platform system, and individual breed user need not to purchase water quality testing equipment alone, also need not to count by oneself to the quality of water change, can obtain high-quality water and detect and report an emergency and ask for help or increased vigilance the management and control, reduces manpower and equipment cost to minimum simultaneously.

It should be noted that, when any user information or fishpond identification or container identification changes, the information service platform database needs to update the stored user information-fishpond identification-container identification correspondence table in time, and add, modify, or delete relevant values to the database.

The third embodiment of the invention relates to an aquaculture water quality detection and monitoring method. Substantially the same as the second embodiment. The difference between the embodiment and the second embodiment is that the embodiment localizes the aquaculture water quality detection monitoring method, the water quality detection equipment stores the user information-fishpond identification-container identification corresponding relation table, and the relation table is added, modified and deleted.

When the water quality detection equipment receives a submission container from a culture user, identifying a container identifier of the submission container, and determining a fishpond identifier and user information corresponding to the submission identifier according to a stored user information-fishpond identifier-container identifier correspondence table; performing water quality detection on the water body in the inspection container, and analyzing water quality detection data; and feeding back the water quality detection data and the analysis result of the fish pond to the corresponding culture user according to the determined fish pond identification and the user information.

A fourth embodiment of the present invention relates to an aquaculture water quality detection monitoring system, as shown in fig. 2, comprising:

the first registration module is used for registering the culture users, acquiring user information of the culture users, distributing fishpond identifications to fishponds owned by the culture users, and indicating the culture users to pick up inspection containers distributed to the fishponds owned by the culture users. The user information includes at least: user account, user identification, user contact information, and the like.

The first storage module is used for storing the corresponding relation among the user information of each culture user, the fishpond identification of the fishpond owned by the culture user and the container identification of the submission container distributed to the fishpond; the container identifier of the submission container may be a number identifier, a character identifier, a symbol identifier, a two-dimensional code identifier, a one-dimensional code identifier, or a combination thereof.

The first identification module is used for identifying the container identification of the submission container from the culture user.

And the first searching module is used for determining the fishpond identification and the user information corresponding to the container identification identified by the first identification module according to the corresponding relation stored by the first storage module.

And the first detection module is used for detecting the water quality of the water body in the inspection container. The water quality detection categories at least include: nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH value, dissolved oxygen amount and the like.

And the first analysis module is used for analyzing the water quality detection data generated by the first detection module.

And the first feedback module is used for feeding back the water quality detection data and/or the analysis result of the fish pond to the corresponding culture user according to the fish pond identification and the user information determined by the first search module.

Wherein the first analysis module further comprises:

the water quality judgment submodule is used for judging whether the water quality detection data of each category exceed the preset water quality data safety range of the corresponding category or not and generating an analysis result, wherein the analysis result at least comprises a judgment conclusion and a corresponding mode;

and the trend analysis submodule is used for analyzing the change trend of the water quality detection data in the specified time period and generating an analysis result, wherein the analysis result at least comprises a water quality change trend conclusion and a corresponding mode.

The first feedback module may include one or any combination of the following:

the system comprises a mobile phone short message notification sub-module, a mobile phone voice notification sub-module, a client side APP text information pushing sub-module, a client side APP voice information pushing sub-module and a client side APP detection data query display sub-module.

Through this embodiment for breed user in an area can share aquaculture water quality testing module, analysis module, accepts the whole water quality control and the management of system, and individual breed user need not to purchase water quality testing equipment alone, also need not to count the quality of water change by oneself, has reduced manpower and equipment cost when obtaining high-quality water detection and management and control.

A fifth embodiment of the present invention relates to an information service platform system connected to water quality monitoring apparatuses installed in different areas through a wired or wireless network, as shown in fig. 3, the information service platform system including:

and the second registration module is used for registering the culture users, acquiring the user information of the culture users, distributing the fishpond identifications to the fishponds owned by the culture users, and indicating the culture users to pick up the inspection containers distributed to the fishponds owned by the culture users. The user information includes at least: user account, user identification, user contact information, and the like.

The second storage module is used for storing the corresponding relation among the user information of each culture user, the fishpond identification of the fishpond owned by the culture user and the container identification of the submission container distributed to the fishpond; the container identifier of the submission container may be a number identifier, a character identifier, a symbol identifier, a two-dimensional code identifier, a one-dimensional code identifier, or a combination thereof.

The first receiving module is used for receiving the container identification and the water quality detection data from the water quality detection equipment.

And the second searching module is used for determining the fishpond identification and the user information corresponding to the container identification received by the first receiving module according to the corresponding relation stored by the second storage module.

The second storage module is also used for storing the water quality detection data received by the first receiving module and the fishpond identification determined by the second searching module in a correlation manner.

A sixth embodiment of the present invention relates to a water quality testing apparatus, which is installed in service stations in different areas and connected to an information service platform system through a wired or wireless network, and as shown in fig. 3, includes:

the second identification module is used for identifying the container identification of the submission container from the culture user; the container identifier of the submission container may be a number identifier, a character identifier, a symbol identifier, a two-dimensional code identifier, a one-dimensional code identifier, or a combination thereof.

And the second sending module is used for sending the container identifier identified by the second identification module to the information service platform system.

And the second receiving module is used for receiving the fishpond identification and the user information corresponding to the container identification from the information service platform system.

The second detection module is used for detecting the water quality of the water body in the inspection container; the water quality detection categories at least include: nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH value, dissolved oxygen amount and the like.

The second analysis module is used for analyzing the water quality detection data generated by the second detection module;

The second sending module is further used for sending the water quality detection data generated by the second detection module to the information service platform system.

Wherein the second analysis module may further comprise:

The second feedback module may include one or any combination of the following:

A seventh embodiment of the present invention relates to an information service platform system connected to water quality monitoring apparatuses installed in different areas through a wired or wireless network, as shown in fig. 4, including:

and the third registration module is used for registering the culture users, acquiring the user information of the culture users, distributing the fishpond identifications to the fishponds owned by the culture users, and indicating the culture users to pick up the inspection containers distributed to the fishponds owned by the culture users. The user information includes at least: user account, user identification, user contact information, and the like.

The third storage module is used for storing the corresponding relation among the user information of each culture user, the fishpond identification of the fishpond owned by the culture user and the container identification of the submission container distributed to the fishpond; the container identifier of the submission container may be a number identifier, a character identifier, a symbol identifier, a two-dimensional code identifier, a one-dimensional code identifier, or a combination thereof.

And the third receiving module is used for receiving the water quality detection data and the corresponding container identification from the water quality detection equipment.

And the third searching module is used for determining the fishpond identification and the user information corresponding to the container identification received by the third receiving module according to the corresponding relation stored by the third storage module.

the third storage module is also used for storing the water quality detection data received by the third receiving module and storing the water quality detection data in association with the fishpond identification determined by the third searching module.

Wherein the third analysis module may further include:

The third feedback module may include one or any combination of the following:

An eighth embodiment of the present invention relates to a water quality testing apparatus, which is installed in service stations in different areas and connected to an information service platform system through a wired or wireless network, and as shown in fig. 4, includes:

the third identification module is used for identifying the container identification of the submission container from the culture user; the container identifier of the submission container may be a number identifier, a character identifier, a symbol identifier, a two-dimensional code identifier, a one-dimensional code identifier, or a combination thereof.

The third detection module is used for detecting the water quality of the water body in the inspection container; the water quality detection categories at least include: nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH value, dissolved oxygen amount and the like.

It should be noted that the fourth to eighth embodiments of the present invention are system examples corresponding to the first to third embodiments, and the fourth to eighth embodiments of the present invention may be implemented in cooperation with the first to third embodiments. The related technical details mentioned in the first to third embodiments are still valid in the fourth to eighth embodiments of the present invention, and are not described herein again in order to reduce the repetition. Accordingly, the related-art details mentioned in the fourth to eighth embodiments of the present invention can also be applied to the first to third embodiments.

It should be noted that, in the present embodiment, each of the modules is a logic module, and in practical applications, one logic module may be one physical module, may also be a part of one physical module, and may also be implemented by a combination of a plurality of physical modules. In addition, in order to highlight the innovative part of the present invention, a module or an apparatus that is not so closely related to solve the technical problem proposed by the present invention is not introduced in the present embodiment, but it does not indicate that there is no other module or apparatus in the present embodiment.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Claims

1. An aquaculture water quality detection monitoring method is characterized by comprising the following steps:

registering a culture user in advance, acquiring user information of the culture user, distributing the fishpond identification to a fishpond owned by the culture user, and indicating the culture user to pick up a submission container distributed to the fishpond;

the method comprises the following steps that a culture user scans and recognizes container identification on a submission container through a mobile phone APP or corresponding equipment of a service station, the submission container is bound with a certain fish pond of the culture user, and the corresponding relation between the container identification of the submission container and the fish pond identification of the fish pond is uploaded;

when receiving a submission container from the culture user, identifying a container identifier of the submission container, and determining a fishpond identifier and user information corresponding to the container identifier according to the corresponding relation;

and feeding back the water quality detection data and/or analysis results of the fishpond to corresponding culture users according to the determined fishpond identification and user information.

2. The method for detecting and monitoring the quality of the aquaculture water according to claim 1, wherein the analyzing the water quality detection data comprises:

Analyzing the change trend of the water quality detection data in the appointed time period, and generating an analysis result, wherein the analysis result at least comprises a water quality change trend conclusion and a corresponding mode.

3. The method for detecting and monitoring the quality of the aquaculture water body according to claim 1, wherein the container identifier of the submission container at least comprises one of the following or any combination thereof:

the system comprises a digital mark, a character mark, a symbol mark, a two-dimensional code mark and a one-dimensional code mark;

the water quality detection category at least comprises one or any combination of the following categories:

nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH value and dissolved oxygen amount.

4. The method for detecting and monitoring the quality of the aquaculture water according to claim 1, wherein the user information comprises at least one of the following: a user account, a user identification, and/or a user contact;

the mode of feeding back the water quality detection data and/or analysis results of the fishpond to the corresponding culture users comprises one or any combination of the following modes:

the method comprises the following steps of mobile phone short message notification, mobile phone voice notification, client application program APP text information pushing, client APP voice information pushing and client APP query interface display.

5. An aquaculture water quality detection monitoring system, comprising:

the first registration module is used for registering a culture user in advance, acquiring user information of the culture user, distributing a fishpond identifier for a fishpond owned by the culture user, and indicating the culture user to draw a submission container distributed for the fishpond; the method comprises the following steps that a culture user scans and recognizes container identification on a submission container through a mobile phone APP or corresponding equipment of a service station, the submission container is bound with a certain fish pond of the culture user, and the corresponding relation between the container identification of the submission container and the fish pond identification of the fish pond is uploaded;

the first feedback module is used for feeding back the water quality detection data and/or the analysis result of the fishpond to the corresponding culture user according to the fishpond identification and the user information determined by the first search module;

6. The aquaculture water quality detection monitoring system of claim 5 wherein said first analysis module comprises:

the water quality judgment submodule is used for judging whether the water quality detection data of each category exceed a preset water quality data safety range of a corresponding category or not and generating an analysis result, wherein the analysis result at least comprises a judgment conclusion and a corresponding mode; and/or

7. The aquaculture water quality detection monitoring system of claim 5, wherein the container identifier of the submission container comprises at least one of the following or any combination thereof:

a digital identifier, a text identifier, a symbol identifier, a two-dimensional code identifier, and/or a one-dimensional code identifier;

the first feedback module comprises one or any combination of the following:

8. The utility model provides an information service platform system which characterized in that links to each other with the water quality testing equipment who sets up in different regions through wired or wireless network, includes:

the second registration module is used for registering the culture users, acquiring user information of the culture users, distributing fishpond identifications to fishponds owned by the culture users, and indicating the culture users to pick up inspection containers distributed to the fishponds owned by the culture users;

a first receiving module for receiving a container identification from the water quality detection device;

9. A water quality testing apparatus, characterized in that, service stations installed in different areas are connected to the information service platform system of claim 8 through a wired or wireless network, comprising:

10. The utility model provides an information service platform system which characterized in that links to each other with the water quality testing equipment who sets up in different regions through wired or wireless network, includes:

the third registration module is used for registering the culture users, acquiring user information of the culture users, distributing fishpond identifications to fishponds owned by the culture users, and indicating the culture users to pick up inspection containers distributed to the fishponds owned by the culture users;

the third feedback module is used for feeding back the water quality detection data and/or the analysis result of the fishpond to the corresponding culture user according to the fishpond identification and the user information determined by the third searching module;

11. A water quality testing apparatus, characterized in that service stations installed in different areas are connected to the information service platform system of claim 10 through a wired or wireless network, comprising:

and the third sending module is used for sending the container identifier identified by the third identification module and the water quality detection data of the third detection module to the information service platform system.