Movatterモバイル変換


[0]ホーム

URL:


CN107643373B - Aquaculture water quality detection monitoring method and system - Google Patents

Aquaculture water quality detection monitoring method and system
Download PDF

Info

Publication number
CN107643373B
CN107643373BCN201610549028.XACN201610549028ACN107643373BCN 107643373 BCN107643373 BCN 107643373BCN 201610549028 ACN201610549028 ACN 201610549028ACN 107643373 BCN107643373 BCN 107643373B
Authority
CN
China
Prior art keywords
container
water quality
module
identification
fishpond
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201610549028.XA
Other languages
Chinese (zh)
Other versions
CN107643373A (en
Inventor
沈杰
黄玉强
杨小龙
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Zhejiang Celefish Technology Co ltd
Original Assignee
Zhejiang Celefish Technology Co ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Zhejiang Celefish Technology Co ltdfiledCriticalZhejiang Celefish Technology Co ltd
Priority to CN201610549028.XApriorityCriticalpatent/CN107643373B/en
Publication of CN107643373ApublicationCriticalpatent/CN107643373A/en
Application grantedgrantedCritical
Publication of CN107643373BpublicationCriticalpatent/CN107643373B/en
Activelegal-statusCriticalCurrent
Anticipated expirationlegal-statusCritical

Links

Images

Landscapes

Abstract

The invention discloses a method and a system for detecting and monitoring the quality of aquaculture water, which save the corresponding relation among user information of each aquaculture user, a fishpond identifier of a fishpond owned by the aquaculture user and a container identifier of a submission container distributed to the fishpond; when receiving 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; detecting and analyzing the water quality of the water in the inspection container; and feeding back the water quality detection data and/or analysis results of the fish pond to the corresponding culture users according to the determined fish pond identification and the user information. Through this mode for breed user in an area can the same water quality testing equipment of sharing, 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 to the quality of water change by oneself, has reduced manpower and equipment cost when obtaining high-quality water detection and management and control.

Description

Aquaculture water quality detection monitoring method and system
Technical Field
The invention relates to an intelligent aquaculture management and control technology, in particular to an intelligent aquaculture water quality detection and monitoring technology.
Background
In the culture operation of the fishpond, the water quality environment of the fishpond plays an important role in the growth of fish. The quality of the water quality is determined by the content of nitrite, ammonia nitrogen, hydrogen sulfide, PH value and the like in the aquaculture water. In the culture process, the indexes are too high, which brings great harm to cultured aquatic products and even causes large-area death of fishes.
Corresponding equipment and instruments are needed for monitoring the contents of nitrite, ammonia nitrogen, hydrogen sulfide, PH value and the like, the equipment and the instruments are expensive, ordinary fishermen cannot buy the equipment and the instruments, and only the similar aquatic association organization is used for sampling water quality monitoring once and for a while, but the problem of the water quality of the fishpond of the fishermen cannot be solved, and the water quality indexes of each fishpond are different. Or, fishermen find and die, judge that water quality problems may occur, seek professional water quality monitoring help, but late. In addition, currently, fishermen can purchase pH test paper to monitor the pH value, and face (1) that only the pH value can be monitored, and other important data cannot be monitored; (2) the pH value monitored cannot well judge the current pH value and what measures should be taken due to the knowledge limitation of fishermen and the limitation of test paper monitoring; (3) the PH value of the self-test of fishermen has no continuous data record, and the pH value is lost after the test, so that continuous data storage and analysis cannot be carried out.
Disclosure of Invention
The invention mainly solves the technical problem of providing the method and the system for detecting and monitoring the quality of the aquaculture water, so that culture users in one area can share the same water quality detection equipment, individual culture users do not need to buy the water quality detection equipment independently, and the implementation cost is reduced while the high-quality water detection and monitoring are obtained.
In order to solve the technical problem, embodiments of the present invention provide a method for detecting and monitoring the quality of an aquaculture water body, including:
each monitored fish pond is distributed with at least one inspection container, each fish pond corresponds to a fish pond mark, and each inspection container is provided with a container mark;
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 allocated to the fishpond;
when receiving 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 the stored corresponding relation;
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/or analysis results of the fish pond to the corresponding culture users according to the determined fish pond identification and the user information.
The embodiments of the invention also provide a system for detecting and monitoring the quality of the aquaculture water body, which comprises:
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 first identification module is used for identifying the container identification of the submission container from the culture user;
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;
the first detection module is used for detecting the water quality of the water body in the inspection container;
the first analysis module is used for analyzing the water quality detection data generated by the first detection module;
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;
the first storage module is also used for storing the water quality detection data detected by the first detection module.
Each embodiment of the present invention further provides an information service platform system, which is connected to water quality detection devices disposed in different areas through a wired or wireless network, and includes:
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 first receiving module is used for receiving the container identification from the water quality detection equipment;
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;
and the first sending module is used for sending the fishpond identification and the user information determined by the second searching module to the water quality detection equipment.
The embodiment of the invention also provides a water quality detection device, which is arranged at service stations in different areas and is connected with an information service platform system through a wired or wireless network, and comprises:
the second identification module is used for identifying the container identification of the submission container from the culture user;
the second sending module is used for sending the container identifier identified by the second identification module to the information service platform system;
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 second analysis module is used for analyzing the water quality detection data generated by the detection module;
and the second 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 received by the second receiving module.
Each embodiment of the present invention further provides an information service platform system, which is connected to water quality detection devices disposed in different areas through a wired or wireless network, and includes:
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 third receiving module is used for receiving the water quality detection data and the corresponding container identification from the water quality detection equipment;
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 analysis module is used for analyzing the water quality detection data received by the third receiving module;
the third 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 third searching module;
the third storage module is also used for storing the water quality detection data received by the third receiving module.
The embodiment of the invention also provides a water quality detection device, which is arranged at service stations in different areas and is connected with an information service platform system through a wired or wireless network, and comprises:
the third identification module is used for identifying the container identification of the submission container from the culture user;
the third detection module is used for detecting the water quality of the water body in the inspection container;
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.
Compared with the prior art, the implementation mode of the invention has the main differences and the effects that: each monitored fish pond is distributed with at least one inspection container, each fish pond corresponds to a fish pond mark, and each inspection container is provided with a container mark; 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 allocated to the fishpond; when receiving 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; carrying out water quality detection and analysis on the water body in the inspection container; and feeding back the water quality detection data and/or analysis results of the fish pond to the corresponding culture users according to the determined fish pond identification and the user information. Through this mode for breed user in an area can the same water quality testing equipment of sharing, 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 to the quality of water change by oneself, has reduced manpower and equipment cost when obtaining high-quality water detection and management and control.
As a further improvement, the water quality detection data is analyzed, including:
judging whether the water quality detection data of each category exceed a preset water quality data safety range of a corresponding category, and generating an analysis result, wherein the analysis result at least comprises a judgment conclusion and a corresponding mode; and/or
And analyzing the change trend of the water quality detection data in the specified time period to generate an analysis result, wherein the analysis result at least comprises a water quality change trend conclusion and a corresponding mode. Therefore, the water quality change trend can be comprehensively counted and analyzed by the system, and corresponding water quality deterioration early warning and a specific water quality treatment mode are carried out on the breeding users. Or when the system monitors that the deteriorated water quality is improved and meets the qualified requirement (along with treatment), a suggestion for stopping the continuous improvement of the water quality is given so as to prevent the water quality from being reversely deteriorated due to the excessive improvement.
As a further improvement, the container identifier of the submission container may be one of the following or any combination thereof: a number identification, a text identification, a symbol identification, a two-dimensional code identification, and/or a one-dimensional code identification. And thus can be quickly identified by the device.
As a further improvement, the method may further include: registering the aquaculture user in advance, acquiring user information of the aquaculture user, allocating a fishpond identification to a fishpond owned by the aquaculture user, and allocating a submission container to the fishpond.
As a further refinement, the user information includes at least one of: user account, user identification, and/or user contact, etc.
As a further improvement, the way of feeding back the water quality detection data and/or the analysis result to the corresponding breeding users may include: 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, or client APP query interface display and the like.
Drawings
FIG. 1 is a flow chart of a method for detecting and monitoring the quality of an aquaculture water body according to a first embodiment of the invention;
FIG. 2 is a structural diagram of a water quality detecting and monitoring system for aquaculture according to a fourth embodiment of the invention;
FIG. 3 is a diagram showing the construction of an information service platform system and a water quality testing apparatus according to a fifth sixth embodiment of the present invention;
fig. 4 is a structural view of an information service platform system and a water quality testing apparatus according to a seventh eighth embodiment of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
The first embodiment of the invention relates to an aquaculture water quality detection and monitoring method. In the embodiment, service stations are arranged in different areas, water quality detection equipment is arranged in the service stations, and the water quality detection equipment is connected to a unified information service platform through a wired or wireless network. The water quality detection equipment can be comprehensive equipment and integrates detection equipment for nitrite concentration, ammonia nitrogen concentration, hydrogen sulfide concentration, PH value, dissolved oxygen and the like.
When an aquaculture user wants to receive water quality detection monitoring, registration can be carried out in modes of a client (mobile phone) application program APP and the like, the information service platform obtains user information of the aquaculture user, unique corresponding fishpond identification is distributed to each fishpond owned by the aquaculture user, and the corresponding relation between the user information and the fishpond identification is stored. And for a user with a plurality of fishponds, the user information of the user corresponds to a plurality of fishpond identifications.
Then, a service station can provide inspection containers, such as inspection bottles, to a user, each inspection container is provided with a container identifier, the user can scan and recognize the container identifier on the inspection container through a mobile phone APP (or corresponding equipment of the service station), the inspection container is bound with a certain fish pond of an aquaculture user, the corresponding relation between the container identifier of the inspection container and the fish pond identifier of the fish pond is uploaded to an information service platform, and an information service platform database stores the user information of each aquaculture user, the corresponding relation between the fish pond identifier owned by the aquaculture user and the container identifier of the inspection container allocated to the fish pond (a user information-fish pond identifier-container identifier corresponding relation table), as shown in table 1. The container mark can be composed of a number mark, a character mark, a symbol mark, a two-dimensional code mark, a one-dimensional code mark and the like; in order to automatically recognize the container identifier, a two-dimensional code identifier or a one-dimensional code identifier is preferably used. The user information may include a user account, a user identification, a user contact, and the like.
User accountContact meansFishpond markContainer label
Zhang three135********Fish pond 1Container identification 1 two-dimensional code
Li Si159********Fishpond 22 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 second embodiment of the invention relates to a method for detecting and monitoring the quality of aquaculture water, which is substantially the same as the first embodiment. The difference between the present embodiment and the first embodiment is that in the first embodiment, the information service platform system analyzes the water quality detection data of the water body in the fish pond of the culture user, and feeds back the water quality detection data and the analysis result to the corresponding culture user; in this embodiment, the water quality detection device of the service station may analyze the water quality detection data of the water body in the fish pond of the aquaculture user, and feed back the water quality detection data and the analysis result to the corresponding aquaculture user. The information service platform system only needs to receive the container identification identified by the water quality detection equipment from the water quality detection equipment, and determines the fishpond identification and the user information corresponding to the container identification according to the stored user information-fishpond identification-container identification corresponding relation table; and sending the determined fishpond identification and the user information to the water quality detection equipment.
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.
The first storage module is also used for storing the water quality detection data detected by the first detection 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.
And the first sending module is used for sending the fishpond identification and the user information determined by the second searching module to the water quality detection equipment.
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;
and the second 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 received by the second receiving 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 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 second 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.
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 analysis module is used for analyzing the water quality detection data received by the third receiving module;
the third 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 third searching 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 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 third 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.
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.
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.
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 (11)

CN201610549028.XA2016-07-122016-07-12Aquaculture water quality detection monitoring method and systemActiveCN107643373B (en)

Priority Applications (1)

Application NumberPriority DateFiling DateTitle
CN201610549028.XACN107643373B (en)2016-07-122016-07-12Aquaculture water quality detection monitoring method and system

Applications Claiming Priority (1)

Application NumberPriority DateFiling DateTitle
CN201610549028.XACN107643373B (en)2016-07-122016-07-12Aquaculture water quality detection monitoring method and system

Publications (2)

Publication NumberPublication Date
CN107643373A CN107643373A (en)2018-01-30
CN107643373Btrue CN107643373B (en)2021-04-06

Family

ID=61108165

Family Applications (1)

Application NumberTitlePriority DateFiling Date
CN201610549028.XAActiveCN107643373B (en)2016-07-122016-07-12Aquaculture water quality detection monitoring method and system

Country Status (1)

CountryLink
CN (1)CN107643373B (en)

Family Cites Families (7)

* Cited by examiner, † Cited by third party
Publication numberPriority datePublication dateAssigneeTitle
CN201681479U (en)*2010-04-272010-12-22天津科技大学Fishpond dissolved oxygen detection and wireless transmission system based on GSM techonology
EP2392907A1 (en)*2010-06-012011-12-07Hach Lange GmbHSystem for identifying an analyte in a water sample
CN203012458U (en)*2012-11-212013-06-19广州广大通电子科技有限公司Aquaculture online water quality monitoring system
CN104165977A (en)*2014-07-212014-11-26小米科技有限责任公司Water quality alarming method and device, and water-consuming device
CN104570994A (en)*2014-08-082015-04-29柯远珍Automatic monitoring method for aquaculture
CN104833785A (en)*2015-05-282015-08-12巩向海Water quality detecting method, device and system
CN205103592U (en)*2015-09-252016-03-23武汉市农业机械化科学研究所Aquaculture thing networking monitored control system of area feedback

Also Published As

Publication numberPublication date
CN107643373A (en)2018-01-30

Similar Documents

PublicationPublication DateTitle
Hegarty et al.Cattle selected for lower residual feed intake have reduced daily methane production
JP5998744B2 (en) Colony detection device, medium information registration system, hygiene management system, and program
CN106204061A (en)A kind of organic domestic animal grow, butchers, distribution process monitoring and can system for tracing and managing
US20180114168A1 (en)System and method for digital supply chain traceability
US20040177011A1 (en)Food contamination tracking system
CN109460945A (en)Cultivation information monitoring method based on Internet of Things
WO2004050835A3 (en)Predicting animal performance
EneThe relevance of traceability in the food chain
CN113191655B (en)Feeding method, device and computer readable storage medium
CN106447344A (en)Quarantine identifier traceability system for livestock and livestock meat products
CN115250950A (en)Artificial intelligence-based livestock and poultry pig farm inspection method and system
CN112445321A (en)Article processing method and device and electronic equipment
CN117709971A (en)Cultivation information visual traceability system and method based on Internet of things
CN103439470A (en)Quick food quality tracing detection system based on network
CN107643373B (en)Aquaculture water quality detection monitoring method and system
JP6131738B2 (en) Information provision system, hygiene management system, and program
JP5943314B2 (en) Image analysis system, medium information registration system, program and hygiene management system
Wannee et al.A flexible water monitoring system for pond aquaculture
CN205540916U (en)Meat products quality monitored control system
Kimura et al.Evaluation of Deep Learning-Based Monitoring of Frog Reproductive Phenology
JP6070172B2 (en) Medium information registration system, program and hygiene management system
Haron et al.Remote water quality monitoring system using wireless sensors
CN112819359A (en)Method, device, equipment and storage medium for whole-course management and control of crabs
CN212622194U (en)Fishery aquaculture disease early warning system
CN113971574A (en)Meat product processing process safety tracing method based on Internet of things

Legal Events

DateCodeTitleDescription
PB01Publication
PB01Publication
SE01Entry into force of request for substantive examination
SE01Entry into force of request for substantive examination
CB02Change of applicant information
CB02Change of applicant information

Address after:313000 room 280, building 4, No.11 Keyuan Road, Wuyang street, Deqing County, Huzhou City, Zhejiang Province (Moganshan national high tech Zone)

Applicant after:ZHEJIANG CELEFISH TECHNOLOGY Co.,Ltd.

Address before:313000 Menghu ancient street, jianlinghu Town, Nanxun, Huzhou City, Zhejiang Province

Applicant before:HUZHOU CELEFISH AGRICULTURAL SCIENCE AND TECHNOLOGY Co.,Ltd.

GR01Patent grant
GR01Patent grant

[8]ページ先頭

©2009-2025 Movatter.jp