WO2023033257A1 - Système de surveillance de réservoir d'eau et procédé de surveillance de réservoir d'eau l'utilisant - Google Patents

Système de surveillance de réservoir d'eau et procédé de surveillance de réservoir d'eau l'utilisant Download PDF

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Publication number
WO2023033257A1
WO2023033257A1 PCT/KR2021/017677 KR2021017677W WO2023033257A1 WO 2023033257 A1 WO2023033257 A1 WO 2023033257A1 KR 2021017677 W KR2021017677 W KR 2021017677W WO 2023033257 A1 WO2023033257 A1 WO 2023033257A1
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WIPO (PCT)
Prior art keywords
information
temperature
water tank
water
service server
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PCT/KR2021/017677
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English (en)
Korean (ko)
Inventor
김범준
김희준
Original Assignee
주식회사 신진테크해양
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Publication of WO2023033257A1 publication Critical patent/WO2023033257A1/fr

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    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01KANIMAL HUSBANDRY; AVICULTURE; APICULTURE; PISCICULTURE; FISHING; REARING OR BREEDING ANIMALS, NOT OTHERWISE PROVIDED FOR; NEW BREEDS OF ANIMALS
    • A01K63/00Receptacles for live fish, e.g. aquaria; Terraria
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01KANIMAL HUSBANDRY; AVICULTURE; APICULTURE; PISCICULTURE; FISHING; REARING OR BREEDING ANIMALS, NOT OTHERWISE PROVIDED FOR; NEW BREEDS OF ANIMALS
    • A01K63/00Receptacles for live fish, e.g. aquaria; Terraria
    • A01K63/06Arrangements for heating or lighting in, or attached to, receptacles for live fish
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01KMEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
    • G01K1/00Details of thermometers not specially adapted for particular types of thermometer
    • G01K1/02Means for indicating or recording specially adapted for thermometers
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D23/00Control of temperature
    • G05D23/19Control of temperature characterised by the use of electric means
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06QINFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
    • G06Q50/00Information and communication technology [ICT] specially adapted for implementation of business processes of specific business sectors, e.g. utilities or tourism
    • G06Q50/10Services
    • GPHYSICS
    • G08SIGNALLING
    • G08BSIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
    • G08B21/00Alarms responsive to a single specified undesired or abnormal condition and not otherwise provided for
    • G08B21/18Status alarms

Definitions

  • the present invention relates to a water tank monitoring system and a water tank monitoring method using the same. It relates to a water tank monitoring system built to inform the state of the water tank and a water tank monitoring method using the same.
  • the quality of water in the aquarium directly affects the health and life of the fish living in the aquarium, so special and meticulous management and inspection are required.
  • the present invention was created to solve the above-mentioned problems, and measures the water temperature of the tank and the temperature of the area where the tank is installed at the same time, and based on the measured temperature values, before the fish housed in the tank reach an environment in which they can die. , It relates to a monitoring system built to predict the range of temperature change of a water tank that can change according to the surrounding environment in which the water tank is installed to a remote user so that the user can take preemptive action against an emergency situation and a monitoring method using the same.
  • the water tank monitoring system is a water tank monitoring system for monitoring the environment in a water tank installed on an arbitrary installation space, wherein the water tank monitoring system includes at least one or more of the water temperature of the water tank and the air temperature of the installation space.
  • a sensor unit that collects temperature information including the current water temperature of the water accommodated in the water tank and the current air temperature of the installation space, as well as temperature measurement information; a control unit that is communicatively connected to the sensor unit and is provided to collect the temperature information; a service server communicatively connected to the control unit and configured to generate risk possibility information indicating that the temperature in the water tank may exceed a fish survival temperature; and a notification unit connected to the service server to receive and output the risk possibility information, wherein the sensor unit is installed in the water tank and measures the water temperature in the water tank and provides the measured temperature to the control unit.
  • sensor module and a second sensor module installed at a location spaced apart from the water tank by a predetermined distance to measure the air temperature in the installation space and provide the measured air temperature to the control unit.
  • the water tank monitoring system is provided to input reference temperature information including a reference water temperature and a reference temperature, which are criteria for generating the risk possibility information, and a reference temperature deviation value representing a deviation between the reference water temperature and the reference temperature.
  • the control unit is provided to generate a water tank temperature deviation value by calculating a deviation between the current water temperature and the current air temperature, and when the water tank temperature deviation value exceeds the reference temperature deviation value, the control unit calculates a deviation between the current water temperature and the current air temperature.
  • a deviation value deviation signal is provided to a service server side, and the service server is configured to receive the deviation value deviation signal and generate the risk possibility information.
  • the monitoring system is provided to input a temperature matching signal, which is a control signal for matching the water temperature with the air temperature of the installation space in which the water tank is installed, and an input unit provided to provide the temperature matching signal to the control unit. ; and a temperature control unit mounted on the water tank to vary the temperature of the water in the water tank, wherein the control unit is communicatively connected to the temperature control unit and displays a maximum performance of the temperature control unit installed in the water tank. It is characterized in that it is provided to generate maximum performance information that is information.
  • control unit receives the water temperature and air temperature from the sensor unit after generating the maximum performance information, and adjusts the water temperature to a preset water temperature through the temperature controller within a predetermined time based on the maximum performance information. It is provided to determine whether it can be restored, and when it is determined that the temperature control unit cannot return to the preset water temperature, it is provided to generate a return impossible signal and transmit it to the service server, and the service server generates the return impossible signal. It is characterized in that it is built to generate risk possibility information based on this by receiving it and transmit it to the user terminal.
  • the monitoring system in order to minimize the communication noise generated by the AC power supply, a power supply unit capable of independently supplying power to the monitoring system; a circulation pump unit installed in the water tank to suck in and discharge water contained in the water tank; and a self-generating unit provided to generate power based on the flow of water discharged from the circulation pump unit and provide the power to the power supply side, and is communicatively connected to the control unit.
  • the monitoring system is a criterion for determining that the amount of water discharged from the circulation pump unit is in a normal state, and reference power generation amount information, which is information indicating the amount of power generated by the self-generation unit, is input.
  • An input unit provided Further, the control unit receives a power generation signal generated during power generation from the self-generation unit after receiving the reference generation amount information through the input unit, and is information indicating the amount of power currently generated by the self-generation unit.
  • Current power generation information is generated, compared with the reference power generation information, and when the power amount of the current power generation information is less than the power amount of the reference power generation information, an abnormal signal for generating the risk possibility information is generated and the service server characterized in that it is provided to transmit to the side.
  • the service server is constructed to be able to communicate with at least one or more external service servers including a Korea Meteorological Administration server generating at least one weather information including the highest temperature and lowest temperature of a randomly selected date, and After receiving the temperature information obtained through the sensor unit while collecting the weather information from the service server, the water temperature of the temperature information and the temperature of the weather information are mutually compared, and the water temperature of the water tank according to the temperature of the weather information At least one piece of water temperature change information indicating the change amount is calculated, and when the water temperature change amount exceeds a predetermined reference change amount, the risk possibility information is generated and transmitted to the notification means.
  • a Korea Meteorological Administration server generating at least one weather information including the highest temperature and lowest temperature of a randomly selected date
  • the water tank monitoring system further includes a communication unit installed in each of at least one water tank and configured to generate location information of a location where the water tank is installed, and the service server generates information through the communication unit.
  • the danger possibility information is for returning the water tank temperature deviation value to a normal state from the time point when the water tank temperature deviation value deviated from the reference temperature deviation value.
  • a water tank monitoring system comprising a time required for action, which is a time required for action.
  • the notification unit receives the danger possibility information generated by the service server and outputs the danger possibility information by using one or more signal output methods selected from among an optical signal output method, a sound signal output method, and a vibration signal output method. It is characterized in that it is provided to output.
  • the notification means includes a user terminal provided to be connected to the service server through wired or wireless communication, and the service server is based on a water tank temperature deviation value obtained by calculating a deviation between the current water temperature and the current temperature. It is characterized in that it is provided to generate risk level determination information for dividing the risk possibility information into at least one or more levels and transmit it to the user terminal.
  • the water tank monitoring method is a water tank monitoring method using a water tank monitoring system constructed to monitor the state of the water tank, wherein the water tank monitoring system is provided for measuring the water temperature in the water tank and the air temperature of the area where the water tank is installed.
  • the water tank monitoring method includes a sensor unit, a control unit connected to the sensor unit and configured to calculate a deviation value between water temperature and air temperature, an input unit, a service server and notification unit communicatively connected to the control unit.
  • the information calculation step compares the water tank temperature deviation value generated through the deviation value calculation step with the reference information to determine whether the water tank temperature deviation value is out of the range of the reference information, When it is determined that the water tank temperature deviation value is out of the reference information, a out-of-range signal is generated and transmitted to the service server.
  • the water tank monitoring system further includes a temperature controller mounted on the water tank and provided to vary the water temperature of the water tank, and the water tank monitoring method, through the control unit, measures the temperature of the water tank installed in the water tank.
  • the temperature controller performance calculation step of calculating maximum performance information which is information indicating the maximum performance of the temperature controller, is further included, wherein the information calculation step includes the temperature controller through the temperature controller within a predetermined time based on the maximum performance information.
  • a non-return signal is generated and transmitted to the service server, and the risk possibility information generating step is characterized in that the service server is configured to receive the non-return signal, generate risk possibility information based thereon, and transmit the information to the notification means.
  • the water tank monitoring system may include a circulation pump unit provided to suck and discharge water contained in the water tank; and a self-generating unit provided to generate power based on the flow of water discharged from the circulation pump unit and provide it to the power supply unit, and is communicatively connected to the control unit, wherein the reference information acquisition step is performed through the input unit.
  • the water tank monitoring method includes the input unit After receiving the reference generation amount information through the self-generation unit, receiving a generation signal generated during power generation from the self-generation unit and receiving current generation amount information, which is information indicating the amount of power generated by the current self-generation unit; In the information calculation step, after receiving the current generation amount information from the control unit, comparing it with the reference generation amount information, and when the power amount of the current power generation amount information is less than the amount of power of the reference power generation amount information, the risk It is characterized in that an abnormal signal for generating possibility information is generated and transmitted to the service server side.
  • a service server constructed to be able to communicate with at least one external service server including a meteorological agency server generating at least one weather information is the external service server.
  • the method further includes a water temperature change prediction step of calculating the above, wherein the risk possibility information generating step includes generating the risk possibility information when the water temperature change amount calculated in the water temperature change amount prediction step deviates from a predetermined reference change amount, and the notification means It is characterized by transmission to.
  • the water tank monitoring system monitors the temperature of the water tank and, when the temperature reaches a dangerous level for the fish, provides information on the possibility of danger to the user, thereby preventing the death of the fish in advance. It can provide the effect that can be done.
  • the water temperature in the water tank changes according to the temperature of the space where the water tank is installed, thereby predicting the occurrence of dangerous situations in advance due to rapid changes in air temperature. Accordingly, it is possible to provide an effect of remarkably improving the survival rate of fish by providing an alarm to the user at an earlier time point.
  • the power supply time of the power supply unit can be extended, thereby providing improved user convenience.
  • the operation state of the circulation pump unit can be easily grasped, thereby providing an effect of preventing death of fish that may occur when the operation of the circulation pump unit is stopped.
  • the user can more intuitively grasp risk possibility information, thereby providing an effect of providing improved usability.
  • the signal output method is forcibly changed so that risk potential information can be output, providing an effect of providing related information more clearly. can do.
  • FIG. 1 is a schematic block diagram of a water tank monitoring system according to the present invention.
  • FIG. 2 is a use state diagram showing a state in which the water tank monitoring system according to the present invention is installed.
  • FIG. 3 is an exemplary diagram illustrating the configuration of a water tank monitoring system according to an additional embodiment of the present invention.
  • FIG. 4 is an exemplary diagram illustrating the configuration of a water tank monitoring system according to another additional embodiment of the present invention.
  • FIG. 5 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to an embodiment of the present invention.
  • FIG. 6 is a flow chart illustrating the progress sequence of the water tank monitoring method according to an embodiment of the present invention.
  • FIG. 7 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the first additional embodiment of the present invention.
  • FIG. 8 is a flow chart illustrating the progress sequence of the water tank monitoring method according to the first additional embodiment of the present invention.
  • FIG. 9 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the second additional embodiment of the present invention.
  • FIG. 10 is a flow chart illustrating the progress of the water tank monitoring method according to the second additional embodiment of the present invention.
  • FIG. 11 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the third additional embodiment of the present invention.
  • FIG. 12 is a flow chart illustrating the progress of the water tank monitoring method according to the third additional embodiment of the present invention.
  • FIG. 13 is a use state diagram showing a state in which a forecast screen by date is output to a notification means through the risk possibility information output step of the water tank monitoring method according to the third additional embodiment of the present invention.
  • FIG. 14 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the fourth additional embodiment of the present invention.
  • 15 is a flow chart illustrating the progress of the water tank monitoring method according to the fourth additional embodiment of the present invention.
  • 15 is a flow chart illustrating the progress of the water tank monitoring method according to the fourth additional embodiment of the present invention.
  • FIG. 16 is a use state diagram showing a state in which a corresponding guide screen is output to a notification unit through a risk possibility information output step of a water tank monitoring method according to a fourth additional embodiment of the present invention.
  • 700 power supply unit
  • 710 self-generation unit
  • S service server
  • S1 service server
  • S2 external service server
  • T notification means
  • T1 primary user terminal
  • T2 secondary user terminal
  • S100 Risk possibility information generation step
  • S110 First risk possibility information generation step
  • S120 Second risk possibility information generation step
  • S130 Estimated time of arrival information provision step
  • S140 Action determination step
  • S150 Risk possibility information additional output stage
  • FIG. 1 is a schematic block diagram of a water tank monitoring system according to the present invention
  • FIG. 2 is a use state diagram showing a state in which the water tank monitoring system according to the present invention is installed.
  • the water tank monitoring system 1000 of the present invention includes a sensor unit 100, a control unit 200, an input unit 300, a temperature controller 400, and a circulation pump unit 500. , It is characterized in that it includes a communication unit 600, a power supply unit 700, a service server (S) and a notification means (T).
  • the water tank monitoring system 1000 is characterized in that it is built to monitor the environment in a water tank installed on an arbitrary installation space.
  • the sensor unit 100 constituting the water tank monitoring system 100 is provided to collect temperature information, which is information obtained by measuring at least one of the water temperature of the water tank and the air temperature of the installation space.
  • the temperature information may include a current water temperature of water accommodated in the water tank and a current air temperature of the installation space.
  • the sensor unit 100 includes a first sensor module 110 and a second sensor module 120, and the first sensor module 110 is installed in the water tank to measure the temperature of the water in the water tank to be described later. It is provided to provide corresponding information to the control unit 200 to do.
  • the second sensor module 120 is installed on the installation space to measure the temperature of the installation space and provide corresponding information to the control unit 200 to be described later.
  • the second sensor module 120 may be installed at a location spaced apart from the water tank by a predetermined distance so that the measured air temperature is not affected by the water temperature in the water tank.
  • control unit 200 is provided to collect temperature information measured through the sensor unit 100, and is provided to communicate with the sensor unit.
  • control unit 200 is provided to form one assembly together with the communication unit 600 and the power supply unit 700 to be described later, and may be provided to be detachable from the water tank.
  • the input unit 300 is provided to allow the control unit to input information that is a criterion for determining various types of information, and may be provided to enable communication with the control unit 200, and for the service server. It will be explained in more detail after the description.
  • the temperature control unit 400 is installed in the water tank to vary the temperature of the water in the water tank, and includes a heat transfer module 410 and a cooling module 420.
  • the heat transfer module 410 is installed in the water tank and is provided to increase the water temperature of the water accommodated in the water tank when necessary.
  • the cooling module 420 is installed in the water tank and is provided to lower the water temperature of the water accommodated in the water tank when necessary.
  • the circulation pump unit 500 is installed in the water tank to supply oxygen by inducing circulation of water while suctioning and discharging water accommodated in the water tank, and the circulation pump unit 500 By allowing it to be operated at all times, it is possible to prevent fish in the tank from dying due to lack of oxygen.
  • the power supply unit 700 is for driving the sensor unit 100, the control unit 200, the input unit 300, the temperature controller 400, the circulation pump unit 500 and the communication unit 600. Equipped to supply power.
  • the power supply unit 700 is characterized by including a battery capable of independently supplying power to the monitoring system 1000 in order to minimize communication noise generated by AC power.
  • the battery may be a built-in battery or a replaceable battery.
  • the power supply unit 700 may further include a self-generating unit 710 .
  • the self-generating unit 710 is characterized in that it is provided to generate power based on the flow of water discharged from the circulation pump unit and provide it to the power supply unit 700, and is communicatively connected to the control unit 200. are provided so that
  • the service server (S) is communicatively connected to the control unit 200 and is provided to generate risk possibility information, which is information indicating that the temperature in the tank may exceed the survivable temperature of the fish.
  • risk possibility information is information indicating that the temperature in the tank may exceed the survivable temperature of the fish.
  • the notification means (T) is characterized in that it is provided to be connected to the service server (S) to receive and output the risk possibility information.
  • the notification means (T) receives the risk possibility information generated by the service server (S) and outputs the possibility of danger by using one or more signal output methods selected from among an optical signal output method, a sound signal output method, and a vibration signal output method. Equipped to output information.
  • the notification means (T) may include at least one or more user terminals provided to be connected to the service server (S) through wired/wireless communication, and the user terminals include mobile phones, smart phones, laptop computers, digital broadcasting terminals, and PDAs.
  • PDAs personal digital assistants
  • PMP portable multimedia player
  • navigation slate PC
  • tablet PC watch type terminal
  • glass type terminal glass
  • HMD head mounted display
  • the user terminal may forcibly change the signal output method of the user terminal according to the level of the risk level determination information provided from the service server S, and output the danger possibility information.
  • the risk level determination information is information for dividing the danger possibility information into at least one level based on a water tank temperature deviation value obtained by calculating a deviation between the current water temperature and the current temperature, and determining the risk level determination information. Based on this, the signal output method of the user terminal can be forcibly changed.
  • the signal output method of the user terminal is forcibly converted according to the level of the risk level determination information provided from the service server (S), and the signal output method is forcibly converted.
  • the risk possibility information is output in .
  • the water tank monitoring system monitors the temperature of the water tank, and when the temperature reaches a dangerous level to the fish, provides the user with information on the possibility of danger, thereby preventing fish It is possible to provide an effect capable of preventing mortality in advance.
  • the risk possibility information is generated based on temperature information acquired through the sensor unit 100 described above.
  • the above-described input unit 300 indicates a reference water temperature, a reference air temperature, and a deviation between the reference water temperature and the reference air temperature, which are criteria for generating the risk possibility information.
  • Reference temperature information including a reference temperature deviation value is input.
  • control unit 200 generates a water tank temperature deviation value by calculating a deviation between the current water temperature constituting the temperature information received through the sensor unit 100 and the current temperature.
  • a deviation value deviation signal is provided to the service server.
  • the service server (S) receives the deviation value departure signal from the control unit 200 to generate the danger possibility information, and the danger possibility information is finally output through the notification means.
  • the temperature controller 400 may be used to generate the risk possibility information.
  • the performance determination criterion information is reference information for measuring the maximum performance of the temperature control unit when used in a water tank containing water, and is a target temperature that is a temperature value that is a standard for measuring the performance of the temperature control unit. may contain values.
  • the temperature matching signal is a control signal for matching the water temperature with the air temperature of the installation space in which the water tank is installed.
  • the process of generating risk possibility information based on the temperature control unit is described.
  • the control unit After transmitting the temperature matching signal to the control unit 200, the control unit transmits the temperature matching signal to the temperature controller to increase the temperature of the water.
  • the driving of the temperature controller is performed so as to match the temperature with the temperature.
  • the temperature control unit 400 is operated at maximum output to change the water temperature up to the target temperature value of the performance judgment reference information input through the input unit 300.
  • control unit 200 receiving the temperature matching signal is connected to the temperature controller 400 by communication and generates maximum performance information representing the maximum performance of the temperature controller 400 installed in the water tank.
  • the controller 200 receives the water temperature and air temperature from the sensor unit 100 after generating the maximum performance information, and sets the water temperature through the temperature controller within a predetermined time based on the maximum performance information. It will be judged if it can be returned to the water temperature.
  • the service server (S) receives the irreversible signal, generates the risk possibility information based thereon, and transmits it to the notification unit (T) side.
  • risk possibility information can be generated and provided based on the maximum performance of the temperature controller in actual use, more accurate information can be provided, which can significantly improve the survivability of fish.
  • the circulation pump unit 500 may be used to generate the risk possibility information.
  • the input unit 300 serves as a criterion for determining that the amount of water discharged from the circulation pump unit 500 is in a normal state, and the self-generating unit ( 710), information indicating the amount of power generated is received as input.
  • control unit 200 receives the reference power generation amount information through the input unit 300 and receives a power generation signal generated during power generation from the self power generation unit 710, and currently operates the self power generation unit 710.
  • Current generation amount information which is information indicating the amount of generated power, is generated.
  • control unit 200 compares the current generation amount information with the reference generation amount information, and when the power amount of the current generation amount information is less than the amount of power of the reference generation amount information, an abnormal signal for generating the danger possibility information. It is generated and transmitted to the service server side.
  • the service server (S) receives the abnormal signal, generates the risk possibility information based on it, and transmits it to the notification unit (T) side.
  • FIG. 3 is an exemplary diagram illustrating the configuration of a water tank monitoring system according to an additional embodiment of the present invention. (External service server)
  • the water tank monitoring system is characterized in that it further includes an external service server (S2).
  • S2 external service server
  • the external service server (S2) is provided to include a meteorological agency server that generates at least one weather information, and may include at least one or more external service servers (S2), the external service server (S2) and the above One service server (S1) may be provided so that they can communicate with each other.
  • the weather information includes the highest and lowest temperatures of a randomly selected date.
  • control unit 200 constituting the water tank monitoring system compares the water temperature of the temperature information with the air temperature of the weather information, At least one piece of water temperature change information representing the change in water temperature in the water tank according to the temperature of the water tank is calculated.
  • the service server (S) operates to generate risk possibility information and transmit it to the notification means when the amount of change in water temperature exceeds a predetermined reference amount of change.
  • the service server (S) includes a plurality of changes in water temperature, generates at least one prediction information by date, which is information indicating the plurality of changes in water temperature by date, and transmits it to the notification means (S). .
  • the notification means (S) may output a prediction screen by date, which is a screen showing the prediction information by date, after receiving the prediction information by date.
  • the survival probability of fish can be remarkably improved.
  • the user can more intuitively grasp information on the possibility of risk, thereby providing an effect of providing improved usability.
  • FIG. 4 is an exemplary diagram illustrating the configuration of a water tank monitoring system according to another additional embodiment of the present invention.
  • a water tank monitoring system is characterized by including an external service server and a plurality of notification means.
  • the notification unit is characterized in that it includes a main user terminal (T1) and a secondary user terminal (T2).
  • the water tank monitoring system includes at least one water tank, and includes a communication unit installed in each of the water tanks and configured to generate location information of a location where the water tank is installed.
  • the communication unit may include a GPS module for obtaining location information of the water tank.
  • the service server (S) receives the location information generated through the communication unit and provides it to the notification means (T) side, and at the same time provides risk possibility information to the notification means (T) side.
  • the risk possibility information may include an action required time, which is a time required for action to restore the water tank temperature deviation value to a normal state from a time point when the water tank temperature deviation value deviates from the reference temperature deviation value.
  • the notification means (T) may include at least one or more user terminal (T1) and auxiliary user terminal (T2).
  • the service server (S) is built to collect the location information of the user terminal (T1), the service server (S) is the position indicated by the location information of the water tank and the location information of the user terminal (T1) Estimated time of arrival information, which is information calculated by calculating the time at which the user of the user terminal T1 can arrive at the water tank, can be generated based on the indicated location.
  • the service server (S) generates risk possibility information further including an action required time, which is a time required to return the water temperature in the water tank to a normal range.
  • the danger possibility information may be transmitted to the secondary user terminal T2.
  • the service server (S) includes not only the risk possibility information, but also action required time guide information, which is information informing of the time required for action, and sharing completion information, which is information indicating that transmission of risk possibility information to the auxiliary user terminal has been performed. may be additionally generated and provided to the user terminal.
  • the user terminal may be provided with the risk possibility information and output a corresponding guide screen formed to provide a countermeasure to the user terminal.
  • the corresponding guide screen includes a location output section (MS) for outputting location information indicating the location of the water tank, a risk possibility information output section (ES) for outputting the risk potential information, and information informing of time required for action.
  • MS location output section
  • ES risk possibility information output section
  • TS time required action guide section
  • SHS sharing completion guide section
  • FIG. 5 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to an embodiment of the present invention
  • FIG. 6 is a flow chart illustrating the progress sequence of the water tank monitoring method according to an embodiment of the present invention.
  • the water tank monitoring method of the present invention is based on a water tank monitoring system built to monitor the state of the water tank.
  • the water tank monitoring system includes a sensor unit provided to measure the water temperature in the water tank and the air temperature of the area where the water tank is installed, a control unit connected to the sensor unit and configured to calculate a deviation value between the water temperature and the air temperature, an input unit, It includes a service server and notification means connected to the control unit in communication.
  • the water tank monitoring method (S1000) includes a standard information acquisition step (S10), temperature information acquisition step (S50), deviation value calculation step (S60), information calculation step (S70), risk possibility information generation step (S100), and risk possibility step. It is characterized by including an information output step (S110).
  • the reference information acquisition step (S10) is a step in which reference information for determining the abnormal state of the water tank is input.
  • the reference information may include one or more values selected from among a reference water temperature and a reference temperature, which are criteria for generating the danger possibility information, and a reference temperature deviation value representing a deviation between the reference water temperature and the reference temperature.
  • the temperature information acquisition step (S50) is a step performed after the reference information acquisition step (S10), and is a step in which the controller acquires temperature information including the water temperature and air temperature through the sensor unit.
  • the temperature information may include temperature information and water temperature information acquired through the sensor unit.
  • the control unit transmits the obtained temperature information to the service server, and then the service server provides the obtained temperature information to the notification unit. Finally, the temperature information may be output by the notification means.
  • the deviation value calculation step (S60) is a step performed by the control unit after the temperature information acquisition step, wherein the control unit receives the temperature information acquired through the sensor unit, and the temperature of the water and air temperature constituting the temperature information The deviation value is calculated and proceeds to generate a bath temperature deviation value.
  • the information calculation step (S70) is a step performed by the control unit after the deviation value calculation step (S60), and more specifically, the water tank temperature deviation value generated through the deviation value calculation step in the control unit and the reference information This is a step of performing comparison with the reference information obtained in the acquisition step (S10).
  • the information calculation step (S70) compares the water tank temperature deviation value generated through the deviation value calculation step (S60) with the reference temperature deviation value of the reference information, so that the water tank temperature deviation value is the reference temperature deviation value. It proceeds to determine whether it is out of the range of .
  • a range deviation signal is generated and transmitted to the service server.
  • the temperature information acquisition step (S50) may be performed again.
  • the risk possibility information generation step (S100) is a step that proceeds through the service server after the information calculation step (S70).
  • the risk possibility information generating step (S100) generates risk possibility information, which is information indicating that the temperature in the tank may exceed the survivable temperature of the fish according to the result of the information calculation step (S70). It goes on.
  • the risk level determination for dividing the risk possibility information into at least one level and determining the risk level may be additionally performed.
  • the signal output method from the notification means including the user terminal may be converted and output in the risk possibility information output step (S120), which will be described later. Let me explain in more detail.
  • the risk possibility information output step (S120) is a step performed after the risk possibility information generation step (S100), and is a step in which the risk possibility information is transmitted and output from the service server to the notification means.
  • the risk possibility information output step (S120) proceeds after the risk level determination step (S110) has been performed prior to the risk possibility information output step (S120), the risk level information output step (S120) is performed, The output method of risk potential information is forcibly converted and output.
  • the output method of the user terminal may be converted from a vibration signal output method to one or more output methods selected from a light signal output method and a sound signal output method.
  • optical signal output method may be converted to any one or more output methods selected from the vibration signal output method and the sound signal output method, and the sound signal output method outputs any one or more signals selected from the optical signal output method and the vibration signal output method. converted into a method and may proceed to output the risk possibility information.
  • FIG. 7 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the first additional embodiment of the present invention
  • FIG. 8 is a flow chart illustrating the progress sequence of the water tank monitoring method according to the first additional embodiment of the present invention. am.
  • a water tank monitoring method is characterized in that it proceeds based on a water tank monitoring system further including a temperature controller.
  • the water tank monitoring method according to the first additional embodiment of the present invention further includes a temperature controller performance calculation step (S20), and compared to the water tank monitoring method according to the above-described embodiment, the As the process proceeds in the same way except for the temperature controller performance calculation step (S20), information calculation step (S70), and risk potential information generation step (S100), detailed descriptions of overlapping contents are omitted for concise description. let it do
  • maximum performance information which is information representing the maximum performance of the temperature controller installed in the water tank, is calculated through the controller.
  • the performance determination criterion information is reference information for measuring the maximum performance of the temperature control unit when used in a water tank containing water, and is a target temperature that is a temperature value that is a standard for measuring the performance of the temperature control unit. may contain values.
  • the temperature matching signal is a control signal for matching the water temperature with the air temperature of the installation space in which the water tank is installed.
  • the temperature controller performance calculation step (S20) is described. After transmitting the temperature matching signal to the control unit 200, the controller transmits the temperature matching signal to the temperature controller to determine the water temperature and The driving of the temperature controller is performed so as to match the temperature.
  • the temperature control unit 400 is operated at maximum output to change the water temperature up to the target temperature value of the performance judgment reference information input through the input unit 300.
  • control unit 200 receiving the temperature matching signal is connected to the temperature controller 400 by communication and generates maximum performance information representing the maximum performance of the temperature controller 400 installed in the water tank.
  • the controller 200 receives the water temperature and air temperature from the sensor unit 100 after generating the maximum performance information, and sets the water temperature through the temperature controller within a predetermined time based on the maximum performance information. It will be judged if it can be returned to the water temperature.
  • the controller 200 determines that the temperature control unit cannot return to the preset water temperature, it generates a non-return signal and transmits it to the service server S.
  • the information calculation step (S70) is performed after the temperature controller performance calculation step (S20), and returns the water temperature to a preset water temperature through the temperature controller within a predetermined time based on the maximum performance information. We proceed to determine if it is possible.
  • the preset water temperature represents a water temperature at which the fish accommodated in the tank may die.
  • the predetermined time represents the time from the time point at which the water temperature in the tank out of the normal water temperature range is confirmed to the point at which the fish in the tank can survive when the water temperature in the tank is maintained.
  • the service server receives the non-return signal, generates risk possibility information based on this, and transmits it to the notification means.
  • FIG. 9 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the second additional embodiment of the present invention
  • FIG. 10 is a flow chart illustrating the progress sequence of the water tank monitoring method according to the second additional embodiment of the present invention.
  • a water tank monitoring method is characterized in that it proceeds based on a water tank monitoring system further including a circulation pump unit.
  • the tank monitoring method according to the second additional embodiment of the present invention further includes a step of acquiring power generation amount information, and compared to the tank monitoring method according to the above-described embodiment, the step of acquiring the reference information, As the process proceeds in the same way except for the power generation information acquisition step and the information calculation step, detailed descriptions of overlapping contents will be omitted in order to proceed with a concise description.
  • the reference information acquisition step (S10) is a step that proceeds through the input unit, and is a standard for determining that the amount of water discharged from the circulation pump unit is in a normal state, and a self-generating unit constituting the circulation pump unit It proceeds to collect reference power generation amount information, which is information representing the amount of power generated by.
  • the generation amount information acquisition step (S30) is a step that proceeds after the reference information acquisition step (S10), and receives a power generation signal generated through a self-generation unit that is communicatively connected to the control unit and obtains current generation amount information from the control unit. It is a step in the process of acquiring
  • control unit receives a power generation signal generated during power generation from the self power generation unit and acquires current power generation amount information, which is information indicating the amount of power currently generated by the self power generation unit.
  • control unit may provide information on the current generation amount to the service server side after acquiring information on the current generation amount acquired through the self-generating unit, and the service server receiving the current generation amount information may send the current generation amount information to the notification unit. It may be configured to transmit information so that the notification means outputs the current amount of power generation information.
  • control unit compares the current power generation amount information with the reference power generation amount information.
  • the information calculation step (S70) after receiving the current generation amount information from the control unit, comparing it with the reference generation amount information, the power amount of the current generation amount information is less than the amount of power of the reference power generation amount information. In this case, an abnormal signal for generating the risk possibility information is generated and transmitted to the service server.
  • the danger possibility information is output through the notification unit through the danger possibility information generation step and the danger possibility information output step.
  • FIG. 11 is a block flow chart illustrating the progress sequence of the tank monitoring method according to the third additional embodiment of the present invention
  • FIG. 12 is a flow chart illustrating the progress sequence of the water tank monitoring method according to the third additional embodiment of the present invention. is. (external service server)
  • the water tank monitoring method according to the third additional embodiment is performed based on the water tank monitoring system further including an external service server.
  • the external service server may include at least one weather station server generating at least one weather information.
  • the water tank monitoring method according to the third additional embodiment of the present invention further includes a weather information acquisition step and a water temperature change estimation step, and the water tank monitoring method according to the above-described embodiment
  • the process proceeds the same except for the weather information acquisition step, the water temperature change prediction step, and the risk possibility information generation step, detailed descriptions of overlapping contents will be omitted for concise description.
  • the weather information acquisition step (S80) is a step that proceeds after the temperature information acquisition step (S50), in which a service server configured to be able to communicate with an external service server collects weather information from the external service server It is a step.
  • the weather information includes precipitation, rainfall, precipitation probability, maximum temperature, minimum temperature, wind direction, wind speed, humidity, weather warning, date, etc. stored in an external service server including the Meteorological Administration server, but is not limited thereto, and overall It may contain weather-related information.
  • a weather information request signal which is a signal for requesting weather information from the service server to the external service server, is generated and provided to the external service server.
  • the weather information request signal may be a signal for requesting weather information including a maximum temperature and a minimum temperature of an arbitrary date.
  • the external service server receives the weather information request signal from the service server, loads weather information stored in the external service server, and provides the weather information to the service server.
  • the water temperature change estimation step (S90) is a step performed after receiving the temperature information acquired through the sensor unit from the control unit.
  • the water temperature change prediction step (S90) compares the water temperature of the temperature information and the temperature of the weather information provided from the external service server, so that the temperature of the water tank that can be changed according to the temperature of the weather information It proceeds to calculate at least one piece of water temperature change amount information representing the change amount of water temperature indicated by the water temperature.
  • the risk possibility information generating step (S100) when the water temperature change amount calculated in the water temperature change amount prediction step is out of a predetermined reference change amount, the risk possibility information is generated.
  • the risk possibility information generating step ( S100 ) may include a first risk possibility information generating step ( S101 ) and a second risk possibility information generating step ( S102 ).
  • the first risk possibility information generation step (S101) is performed after the water temperature change amount prediction step (S90), and as described above, when the water temperature change amount calculated in the water temperature change amount prediction step is out of the preset reference change amount. In this case, it proceeds to generate first risk possibility information, which is information indicating that the water temperature change amount predicted by the service server is out of the reference change amount.
  • the second risk possibility information generating step (S102) is a step performed after the information calculation step (S70) performed by the control unit after the deviation value calculation step (S60) described above.
  • the second risk possibility information generation step (S102) proceeds after the control unit compares the water tank temperature deviation value, which is performed in the information calculation step (S70), with the reference information.
  • an out-of-range signal is generated and transmitted to the service server.
  • the second risk possibility information generating step (S102) proceeds, and the service server receiving the range departure signal generates the second risk possibility, which is information informing that the water tank temperature deviation value is out of the reference temperature deviation value. generate information.
  • a risk possibility information output step in which the first risk possibility information and the second risk possibility information are output proceeds, and the risk possibility information output step includes a first risk possibility information output step (S121) and a second risk possibility information output step (S121). information output step.
  • the first risk possibility information described above is transmitted from the service server to the notification means, output through the notification means T, and provided to the user.
  • the service server transmits the second risk possibility information generated based on the out-of-range signal to the notification means, and outputs the information through the notification means so that the user proceeds to provide
  • the notification means (T) includes a plurality of water temperature change information from the service server, and receives at least one date-by-date prediction information, which is information indicating the plurality of water temperature change amounts by date.
  • the notification means (T) may output a prediction screen by date (WD), which is a screen displaying the prediction information by date.
  • the weather forecast screen WD by date is formed by controlling the temperature within a predetermined range by the weather output section WS configured to output a plurality of weather information by date and the temperature controller constituting the monitoring system. It may be configured to include a temperature maintainability output section KS indicating whether or not the temperature range can be maintained.
  • weather information for at least one date may be output in the weather output section WS.
  • At least one result of determining whether the temperature control unit can maintain a predetermined temperature range on a corresponding day may be output in the temperature maintenance capability output section KS.
  • FIG. 12 is a block flow chart illustrating the progress sequence of the water tank monitoring method according to the fourth additional embodiment of the present invention
  • FIG. 13 is a flow chart illustrating the progress sequence of the water tank monitoring method according to the fourth additional embodiment of the present invention. (Auxiliary user terminal)
  • the water tank monitoring method includes a communication unit installed in each of at least one water tank and provided to generate location information of a location where the water tank is installed, and location information of the water tank generated through the communication unit. It proceeds through a water tank monitoring system further comprising a service server receiving and providing the information to the notification means, a notification means including a main user terminal managing the water tank, and an auxiliary user terminal.
  • the water tank monitoring method further includes a location information acquisition step, an estimated time of arrival information providing step, action determination step, and risk possibility information additional output step. .
  • the tank monitoring method according to the fourth additional embodiment has the location information acquisition step (S40), the estimated arrival time information providing step (S130), and determining whether action is possible, compared to the tank monitoring method according to the above-described embodiment.
  • step S140 the estimated arrival time information providing step
  • step S150 additional output of risk possibility information step S150
  • the location information acquisition step (S40) is a step performed in the service server, and more specifically, the service server acquires the location information of the water tank and the location information of the main user terminal through the communication unit. do.
  • At least one water tank may be provided, and a separate external service server capable of providing map information indicating an area in which the water tank is installed may be further provided to obtain the location information.
  • the step of providing the estimated time of arrival information is a step that proceeds through the service server and the main user terminal after the risk possibility information output step (S120).
  • the user of the main user terminal can arrive at the water tank based on the location indicated by the location information of the water tank and the location information of the notification unit.
  • Estimated time of arrival information which is information calculated by calculating the available time, is generated and provided to the main user terminal.
  • the step of determining whether the action is possible is a step that proceeds through the service server after the step of providing the estimated time of arrival information.
  • the service server compares the expected arrival time and the action required time, which is the time required for action to return the water tank to a normal state, within the action required time. It proceeds to determine whether action is possible.
  • the time required for the action is required for measures to restore the water tank temperature deviation value to a normal state from the time when the water tank temperature deviation value, which is the difference between the water temperature of the water tank and the air temperature of the installation area, deviate from the preset reference temperature deviation value. time can be indicated.
  • step of determining whether action is possible if it is determined that the main user has arrived at the water tank requiring action within the required action time because the expected arrival time does not exceed the required action time, continuous expected time of arrival information can proceed to provide.
  • an additional risk information output step (S150) to be described later is performed.
  • step S150 of additionally outputting risk possibility information after the step of determining whether action is possible (S140), when the service server determines that the expected arrival time exceeds the action required time, the auxiliary user terminal and proceeds to further transmit the risk possibility information to the other side.
  • the service server (S) includes not only the risk possibility information, but also action required time guide information, which is information informing of the time required for action, and sharing completion information, which is information indicating that transmission of risk possibility information to the auxiliary user terminal has been performed. may be additionally generated and provided to the user terminal T1.
  • the user terminal may be configured to output a response guide screen GD formed to provide a countermeasure to the user terminal by receiving the danger possibility information.
  • the response guide screen GD includes a position output section MS outputting positional information indicating the position of the tank A2 requiring action among at least one tank, and risk possibility information outputting the risk potential information.
  • An output section (ES) an action required time guide section (TS) that outputs action required time guide information, which is information indicating the time required for action, and sharing, which is information notifying that transmission of risk potential information to the auxiliary user terminal has proceeded.
  • a sharing completion guidance section (SHS) in which information is output may be included.

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Abstract

Un système de surveillance de réservoir d'eau selon la présente invention, qui surveille un environnement dans un réservoir d'eau installé dans un espace d'installation aléatoire, comprend : une unité de capteur qui collecte des informations de température qui sont des informations obtenues par mesure de la température du réservoir d'eau et/ou de la température de l'espace d'installation ; une unité de commande qui est connectée à l'unité de capteur en communication et est prévue pour collecter les informations de température ; un serveur de service qui est connecté à l'unité de commande en communication et prévu pour générer des informations de possibilité de risque qui sont des informations indiquant que la température dans le réservoir d'eau peut dépasser une température viable pour les poissons ; et un moyen de notification qui est connecté au serveur de service en communication et prévu pour recevoir et délivrer les informations de possibilité de risque.
PCT/KR2021/017677 2021-08-30 2021-11-26 Système de surveillance de réservoir d'eau et procédé de surveillance de réservoir d'eau l'utilisant WO2023033257A1 (fr)

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