CN117329112B - Remote control system of water pump - Google Patents

Abstract

The invention discloses a remote control system of a water pump, which relates to the technical field of remote control of water pumps, and solves the technical problem that the operation of the water pump cannot be regulated, so that peak staggering use cannot be realized in the prior art; acquiring an operation cost coefficient FYI in a water sump through a formula, acquiring a charging standard of a region of the water sump and the power consumption user number of the water sump in the whole day period, acquiring a power consumption number SJp of the water sump in the whole day period through the formula, marking the time period with the lowest power consumption number SJp as an operation time period, and then operating the high-cost water sump according to the operation time period; the operation of the water pump is stopped when electricity is used in a peak so as to achieve the purposes of avoiding peak filling and saving energy, improve the working efficiency and reduce the actual cost.

Description

Remote control system of water pump

Technical Field

The invention relates to the technical field of remote control of water pumps, in particular to a remote control system of a water pump.

Background

The remote control system of the water pump mainly comprises a water department dispatching center, a water plant monitoring center, a communication platform and pump room measurement and control equipment. Because of complex system control requirements, and considering the environmental conditions of a central pump room and a central substation chamber, a control part and a control core adopt high-performance programmable controllers. The detection part is divided into two parts: and one is an analog quantity detecting part. The device mainly comprises a sump water level sensing transmitter, a flow sensing transmitter, a pressure transmitter, a negative pressure transmitter, a temperature sensing transmitter and the like, and the device is used for detecting the operation parameters of a main drainage system of a central pump room. And secondly, a switching value detection part. The state of the vacuum circuit breaker in the high-voltage starting cabinet, the working state and the opening and closing position of the electric valve, and the like are connected with the PLC, so that the running state of the system can be detected.

However, in the prior art, the operation of the water pump cannot be adjusted, so that peak shifting cannot be used, the cost is increased, and the efficiency is reduced.

Disclosure of Invention

The invention aims to provide a remote control system of a water pump, which is characterized in that the operation of the water pump is regulated through an energy-saving regulating unit, a water bin is equidistantly divided into a plurality of water level sections, then the underwater dropping speed of each hour corresponding to the water level sections is obtained, the water discharge quantity of the corresponding water bin is obtained according to the underwater dropping speed and the working time length of the whole day, the supply current of the water pump in the corresponding water bin is obtained, then the voltage is marked as 220V according to the supply voltage standard, and then the operation power of the water pump in the corresponding water bin is obtained through the supply current and the supply voltage; acquiring an operation cost coefficient FYI in the water sump through a formula, marking the corresponding water sump as a high-cost water sump if the operation cost coefficient FYI in the water sump is more than or equal to the operation cost coefficient threshold value, and marking the corresponding water sump as a low-cost water sump if the operation cost coefficient FYI in the water sump is less than the operation cost coefficient threshold value; acquiring a charging standard of a region of a water sump and the number of users in the whole day period, acquiring an electricity consumption number SJp in the whole day period through a formula, marking the time period with the lowest electricity consumption number SJp as an operation time period, and then operating the high-cost water sump according to the operation time period; the operation of the water pump is stopped when the electricity consumption peak and the electricity price are high, so that the purposes of peak avoiding, valley filling and energy saving are achieved, the working efficiency is improved, and the actual cost is reduced;

the aim of the invention can be achieved by the following technical scheme:

a remote control system of a water pump comprises a cloud control platform, a water sump detection unit, an energy-saving regulation unit, a water pump detection unit, a conversion regulation unit, a registration login unit and a database;

the energy-saving adjusting unit is used for adjusting the operation of the water pump, and the specific adjusting process is as follows:

step SS1: equally dividing a water bin into a plurality of water level segments, marking the water level segments with positions o, o=1, 2, … …, m and m as positive integers, then acquiring the water descending rate of each hour corresponding to the water level segments, acquiring the water discharge amount of the corresponding water bin according to the water descending rate and the working time length of the whole day, and marking the water discharge amount of the corresponding water bin as FSi;

step SS2: obtaining a supply current corresponding to a water pump in a water sump, marking the supply current as DLi, marking the voltage as 220V according to a supply voltage standard, obtaining an operation power corresponding to the water pump in the water sump through the supply current and the supply voltage, and marking the operation power of the water pump in the water sump as GLi;

step SS3: obtaining an operation cost coefficient FYI in the water bin through a formula FYI=beta (FSi×b1+GLi×b2), wherein b1 and b2 are proportionality coefficients, b1 is larger than b2 and larger than 0, beta is an error correction factor, and the value is 2.362214; the running cost coefficient FYi in the sump is then compared to a running cost coefficient threshold value: if the running cost coefficient FYI in the water sump is more than or equal to the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is high, marking the corresponding water sump as a high-cost water sump, and if the running cost coefficient FYI in the water sump is less than the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is low, and marking the corresponding water sump as a low-cost water sump;

step SS4: then acquiring a charging standard of a region of the water sump and the number of users of the water sump in the whole day period, marking the charging standard of the water sump in the whole day period and the number of users of the water sump in the whole day period as SFp and YDp, marking the water sump in the whole day period as p, p=1, 2, … … and 24, and then acquiring an electricity utilization number SJp of the water sump in the whole day period through a formula SJp =α (SFp ×b3+ YDp ×b4), wherein b3 and b4 are proportionality coefficients, and b3 is larger than b4 is larger than 0;

step SS5: the lowest period of time for which the electricity consumption number SJp is the operating period is marked, and then the high-cost water sump is operated according to the operating period.

Furthermore, the registration login unit is used for submitting manager information and operator information through the mobile phone terminal to register, and sending the manager information and the operator information which are successfully registered to the database to be stored, wherein the manager information comprises names, ages, time of entering and mobile phone numbers of the real-name authentication of the manager, and the operator information comprises names, ages, time of entering and mobile phone numbers of the real-name authentication of the manager.

Further, the sump detection unit is configured to analyze parameter information of the sump, so as to detect the sump, where the parameter information of the sump includes water level data, flow data and pressure data, the water level data is a distance difference between a water level in the sump and a full water level, the flow data is an average flow velocity of water in the sump, the pressure data is an average water pressure of each area in the sump, the sump is marked as i, i=1, 2, … …, n, n is a positive integer, and a specific analysis and detection process is as follows:

step S1: acquiring a distance difference value between the water level in the water bin and the full water level, and marking the distance difference value between the water level in the water bin and the full water level as Ci;

step S2: acquiring the average flow velocity of water in the water sump, and marking the average flow velocity of water in the water sump as Vi;

step S3: acquiring the average water pressure of each area in the water sump, and marking the average water pressure of each area in the water sump as Yi;

step S4: by the formulaObtaining a detection coefficient Xi of a water sump, wherein a1, a2 and a3 are proportionality coefficients, and a1 is more than a2 and more than a3 is more than 0;

step S5: comparing the detection coefficient Xi of the water sump with a detection coefficient threshold value of the water sump:

if the detection coefficient Xi of the water bin is more than or equal to the detection coefficient threshold value of the water bin, judging that the corresponding water bin needs to be drained, generating a drainage signal and sending the drainage signal to a cloud control platform, and after the cloud control platform receives the drainage signal, generating a water pump operation signal and sending the water pump operation signal to a mobile phone terminal of a manager;

if the detection coefficient Xi of the water bin is smaller than the detection coefficient threshold value of the water bin, judging that the corresponding water bin does not need to be drained, generating a non-drainage signal and sending the non-drainage signal to the cloud control platform, and after the cloud control platform receives the non-drainage signal, generating a water pump stop operation signal and sending the water pump stop operation signal to a mobile phone terminal of a manager.

Further, the water pump detection unit is used for analyzing water pump operation data in the water sump, so as to detect the water pump, the water pump operation data are noise data, interval data and temperature data, the noise data are noise decibel values generated when the water pump in the water sump works, the interval data are buffer time length when the water pump in the water sump is started, the temperature data are temperature values in equipment when the water pump in the water sump operates, the water pump is marked as j, j=1, 2, … …, f and f are positive integers, and the specific analysis and detection process is as follows:

step T1: acquiring a noise decibel value generated by a water pump in a water sump when in operation, and marking the noise decibel value generated by the water pump in the water sump when in operation as FBZf;

step T2: acquiring the buffer time when the water pump in the water sump is started, and marking the buffer time when the water pump in the water sump is started as HCSf;

step T3: acquiring a temperature value of the interior of the equipment when the water pump in the water sump operates, and marking the temperature value of the interior of the equipment when the water pump in the water sump operates as WDZf;

step T4: by the formulaAcquiring a detection coefficient JCf of a water pump in a water sump, wherein c1, c2 and c3 are proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, and e is a natural constant;

step T5: comparing the detection coefficient JCf of the water pump in the water sump with a detection coefficient threshold of the water pump:

if the detection coefficient JCf of the water pump in the water bin is more than or equal to the detection coefficient threshold of the water pump, judging that the water pump in the corresponding water bin is abnormal in operation, generating a water pump abnormal signal and sending the water pump abnormal signal to the cloud control platform, and after the cloud control platform receives the water pump abnormal signal, generating a water pump maintenance signal and sending the water pump maintenance signal to a mobile phone terminal of an operator;

if the detection coefficient JCf of the water pump in the water bin is smaller than the detection coefficient threshold value of the water pump, the water pump in the corresponding water bin is judged to run normally, a water pump normal signal is generated and sent to the cloud control platform, and the cloud control platform sends the water pump normal signal to the mobile phone terminal of the manager.

Further, the conversion adjusting unit is used for analyzing control data of the water pump in the water sump, so that the control of the water pump is converted and adjusted, the control data of the water pump are the average starting and stopping times in the whole day, the average using times in the whole day and the average flow rate in the whole day, and the specific analysis and detection process is as follows:

step TT1: acquiring the average start-stop times of the water pump in the running process, and marking the average start-stop times of the water pump in the running process as CSf;

step TT2: acquiring the average use times of the water pump pipeline in all days, and marking the average use times of the water pump pipeline in all days as SYf;

step TT3: acquiring the average hourly flow rate of the water pump pipeline, and marking the average hourly flow rate of the water pump pipeline as LLf;

step TT4: by the formulaObtaining a water pump regulating coefficient Xf in a water sump, wherein s1, s2 and s3 are proportionality coefficients, and s1 is more than s2 and s3 is more than 0;

step TT5: comparing the water pump adjusting coefficient Xf in the water bin with a water pump adjusting coefficient threshold value:

if the water pump adjusting coefficient Xf in the water bin is more than or equal to the water pump adjusting coefficient threshold value, judging that the adjusting coefficient of the corresponding water pump is high, marking the corresponding water pump as the water pump to be adjusted, setting an adjusting time threshold value at the same time, then sending the water pump to be adjusted and the adjusting time threshold value to the cloud control platform, and controlling the water pump to be adjusted to stop running when the running time of the water pump to be adjusted exceeds the adjusting time threshold value after the cloud control platform receives the water pump to be adjusted and the adjusting time threshold value;

if the water pump regulating coefficient Xf in the water bin is smaller than the water pump regulating coefficient threshold value, judging that the regulating coefficient of the corresponding water pump is low, marking the corresponding water pump as the water pump which is not required to be regulated, then sending the water pump which is not required to be regulated to the cloud control platform, and controlling the water pump which is not required to be regulated to start to operate when the water pump which is required to be regulated stops operating after the cloud control platform receives the water pump which is not required to be regulated.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the operation of the water pump is regulated through the energy-saving regulating unit, the water bin is equally divided into a plurality of water level sections, then the underwater descending rate of each hour corresponding to the water level sections is obtained, the water discharge quantity of the corresponding water bin is obtained according to the underwater descending rate and the working time length of the whole day, the supply current of the water pump in the corresponding water bin is obtained, the voltage is marked as 220V according to the supply voltage standard, and then the operation power of the water pump in the corresponding water bin is obtained through the supply current and the supply voltage; acquiring an operation cost coefficient FYI in the water sump according to a formula, if the operation cost coefficient FYI in the water sump is more than or equal to an operation cost coefficient threshold value, judging that the operation cost of the corresponding water sump is high, marking the corresponding water sump as a high-cost water sump, and if the operation cost coefficient FYI in the water sump is less than the operation cost coefficient threshold value, judging that the operation cost of the corresponding water sump is low, and marking the corresponding water sump as a low-cost water sump; acquiring a charging standard of a region of a water sump and the number of users in the whole day period, acquiring an electricity consumption number SJp in the whole day period through a formula, marking the time period with the lowest electricity consumption number SJp as an operation time period, and then operating the high-cost water sump according to the operation time period; the operation of the water pump is stopped when the electricity consumption peak and the electricity price are high, so that the purposes of peak avoiding, valley filling and energy saving are achieved, the working efficiency is improved, and the actual cost is reduced;

2. according to the invention, the control data of the water pump in the water sump is analyzed through the conversion and adjustment unit, so that the control of the water pump is converted and adjusted, the control data of the water pump is obtained, the water pump adjustment coefficient Xf in the water sump is obtained through a formula, if the water pump adjustment coefficient Xf in the water sump is more than or equal to the water pump adjustment coefficient threshold value, the corresponding water pump is judged to be high, the water pump is marked as the water pump to be adjusted, the adjustment time threshold value is set, then the water pump to be adjusted and the adjustment time threshold value are sent to the cloud control platform, and after the cloud control platform receives the water pump to be adjusted and the adjustment time threshold value, the water pump to be adjusted is controlled to stop running when the running time of the water pump to be adjusted exceeds the adjustment time threshold value; if the water pump adjusting coefficient Xf in the water bin is smaller than the water pump adjusting coefficient threshold value, judging that the adjusting coefficient of the corresponding water pump is low, marking the corresponding water pump as the water pump which does not need to be adjusted, then sending the water pump which does not need to be adjusted to the cloud control platform, and controlling the water pump which does not need to be adjusted to start to operate when the cloud control platform receives the water pump which does not need to be adjusted and stops operating; the water pumps are classified, and the water pumps automatically rotate to achieve the purposes of early finding and processing faults and avoiding water sump faults.

Drawings

The present invention is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

Fig. 1 is a functional block diagram of the present invention.

Detailed Description

The technical solutions of the present invention will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1, a remote control system of a water pump comprises a cloud control platform, a water sump detection unit, an energy-saving regulation unit, a water pump detection unit, a conversion regulation unit, a registration login unit and a database;

the registration login unit is used for submitting manager information and operator information through the mobile phone terminal to register, and sending the manager information and the operator information which are successfully registered to the database to be stored, wherein the manager information comprises the name, age, time of entering and mobile phone number of the identity authentication of the manager, and the operator information comprises the name, age, time of entering and mobile phone number of the identity authentication of the operator;

the water sump detection unit is used for analyzing parameter information of the water sump so as to detect the water sump, the parameter information of the water sump comprises water level data, flow data and pressure data, the water level data is a distance difference value between the water level in the water sump and the full-load water level, the flow data is the average flow speed of water in the water sump, the pressure data is the average water pressure of each area in the water sump, the water sump is marked as i, i=1, 2, … …, n and n are positive integers, and the specific analysis and detection process is as follows:

step S1: acquiring a distance difference value between the water level in the water bin and the full water level, and marking the distance difference value between the water level in the water bin and the full water level as Ci;

step S2: acquiring the average flow velocity of water in the water sump, and marking the average flow velocity of water in the water sump as Vi;

step S3: acquiring the average water pressure of each area in the water sump, and marking the average water pressure of each area in the water sump as Yi;

step S4: by the formulaObtaining a detection coefficient Xi of a water sump, wherein a1, a2 and a3 are proportionality coefficients, and a1 is more than a2 and more than a3 is more than 0;

step S5: comparing the detection coefficient Xi of the water sump with a detection coefficient threshold value of the water sump:

if the detection coefficient Xi of the water bin is more than or equal to the detection coefficient threshold value of the water bin, judging that the corresponding water bin needs to be drained, generating a drainage signal and sending the drainage signal to a cloud control platform, and after the cloud control platform receives the drainage signal, generating a water pump operation signal and sending the water pump operation signal to a mobile phone terminal of a manager;

if the detection coefficient Xi of the water bin is smaller than the detection coefficient threshold value of the water bin, judging that the corresponding water bin does not need to be drained, generating a non-drainage signal and sending the non-drainage signal to the cloud control platform, and after the cloud control platform receives the non-drainage signal, generating a water pump stop operation signal and sending the water pump stop operation signal to a mobile phone terminal of a manager;

the energy-saving adjusting unit is used for adjusting the operation of the water pump, and the specific adjusting process is as follows:

step SS1: equally dividing a water bin into a plurality of water level segments, marking the water level segments with positions o, o=1, 2, … …, m and m as positive integers, then acquiring the water descending rate of each hour corresponding to the water level segments, acquiring the water discharge amount of the corresponding water bin according to the water descending rate and the working time length of the whole day, and marking the water discharge amount of the corresponding water bin as FSi;

step SS2: obtaining a supply current corresponding to a water pump in a water sump, marking the supply current as DLi, marking the voltage as 220V according to a supply voltage standard, obtaining an operation power corresponding to the water pump in the water sump through the supply current and the supply voltage, and marking the operation power of the water pump in the water sump as GLi;

step SS3: obtaining an operation cost coefficient FYI in the water bin through a formula FYI=beta (FSi×b1+GLi×b2), wherein b1 and b2 are proportionality coefficients, b1 is larger than b2 and larger than 0, beta is an error correction factor, and the value is 2.362214; the running cost coefficient FYi in the sump is then compared to a running cost coefficient threshold value: if the running cost coefficient FYI in the water sump is more than or equal to the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is high, marking the corresponding water sump as a high-cost water sump, and if the running cost coefficient FYI in the water sump is less than the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is low, and marking the corresponding water sump as a low-cost water sump;

step SS4: then acquiring a charging standard of a region of the water sump and the number of users of the water sump in the whole day period, marking the charging standard of the water sump in the whole day period and the number of users of the water sump in the whole day period as SFp and YDp, marking the water sump in the whole day period as p, p=1, 2, … … and 24, and then acquiring an electricity utilization number SJp of the water sump in the whole day period through a formula SJp =α (SFp ×b3+ YDp ×b4), wherein b3 and b4 are proportionality coefficients, and b3 is larger than b4 is larger than 0;

step SS5: marking the lowest time period of the electricity consumption number SJp as an operation time period, and then operating the high-cost water sump according to the operation time period;

the water pump detection unit is used for analyzing water pump operation data in the water sump so as to detect the water pump, the water pump operation data are noise data, interval data and temperature data, the noise data are noise decibel values generated when the water pump in the water sump works, the interval data are buffer time length when the water pump in the water sump is started, the temperature data are temperature values in equipment when the water pump in the water sump operates, the water pump is marked as j, j=1, 2, … …, f and f are positive integers, and the specific analysis and detection process is as follows:

step T1: acquiring a noise decibel value generated by a water pump in a water sump when in operation, and marking the noise decibel value generated by the water pump in the water sump when in operation as FBZf;

step T2: acquiring the buffer time when the water pump in the water sump is started, and marking the buffer time when the water pump in the water sump is started as HCSf;

step T3: acquiring a temperature value of the interior of the equipment when the water pump in the water sump operates, and marking the temperature value of the interior of the equipment when the water pump in the water sump operates as WDZf;

step T4: by the formulaAcquiring a detection coefficient JCf of a water pump in a water sump, wherein c1, c2 and c3 are proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, and e is a natural constant;

step T5: comparing the detection coefficient JCf of the water pump in the water sump with a detection coefficient threshold of the water pump:

if the detection coefficient JCf of the water pump in the water bin is more than or equal to the detection coefficient threshold of the water pump, judging that the water pump in the corresponding water bin is abnormal in operation, generating a water pump abnormal signal and sending the water pump abnormal signal to the cloud control platform, and after the cloud control platform receives the water pump abnormal signal, generating a water pump maintenance signal and sending the water pump maintenance signal to a mobile phone terminal of an operator;

if the detection coefficient JCf of the water pump in the water bin is smaller than the detection coefficient threshold of the water pump, judging that the water pump in the corresponding water bin operates normally, generating a water pump normal signal and sending the water pump normal signal to the cloud control platform, and sending the water pump normal signal to a mobile phone terminal of a manager by the cloud control platform;

the conversion regulating unit is used for analyzing control data of the water pump in the water bin, so that the control of the water pump is converted and regulated, the control data of the water pump are the average starting and stopping times in the whole day of the water pump operation process, the average using times in the whole day of the water pump pipeline and the average flow rate in each hour of the water pump pipeline, and the specific analysis and detection processes are as follows:

step TT1: acquiring the average start-stop times of the water pump in the running process, and marking the average start-stop times of the water pump in the running process as CSf;

step TT2: acquiring the average use times of the water pump pipeline in all days, and marking the average use times of the water pump pipeline in all days as SYf;

step TT3: acquiring the average hourly flow rate of the water pump pipeline, and marking the average hourly flow rate of the water pump pipeline as LLf;

step TT4: by the formulaObtaining a water pump regulating coefficient Xf in a water sump, wherein s1, s2 and s3 are proportionality coefficients, and s1 is more than s2 and s3 is more than 0;

step TT5: comparing the water pump adjusting coefficient Xf in the water bin with a water pump adjusting coefficient threshold value:

if the water pump adjusting coefficient Xf in the water bin is more than or equal to the water pump adjusting coefficient threshold value, judging that the adjusting coefficient of the corresponding water pump is high, marking the corresponding water pump as the water pump to be adjusted, setting an adjusting time threshold value at the same time, then sending the water pump to be adjusted and the adjusting time threshold value to the cloud control platform, and controlling the water pump to be adjusted to stop running when the running time of the water pump to be adjusted exceeds the adjusting time threshold value after the cloud control platform receives the water pump to be adjusted and the adjusting time threshold value;

if the water pump regulating coefficient Xf in the water bin is smaller than the water pump regulating coefficient threshold value, judging that the regulating coefficient of the corresponding water pump is low, marking the corresponding water pump as the water pump which is not required to be regulated, then sending the water pump which is not required to be regulated to the cloud control platform, and controlling the water pump which is not required to be regulated to start to operate when the water pump which is required to be regulated stops operating after the cloud control platform receives the water pump which is not required to be regulated.

The working principle of the invention is as follows:

the remote control system of the water pump is characterized in that the operation of the water pump is regulated through an energy-saving regulating unit, a water bin is equidistantly divided into a plurality of water level sections, then the underwater descending rate of each hour corresponding to the water level sections is obtained, the water discharge quantity of the corresponding water bin is obtained according to the underwater descending rate and the working time length of the whole day, the supply current of the water pump in the corresponding water bin is obtained, the voltage is marked as 220V according to the supply voltage standard, and then the operation power of the water pump in the corresponding water bin is obtained through the supply current and the supply voltage; acquiring an operation cost coefficient FYI in the water sump according to a formula, if the operation cost coefficient FYI in the water sump is more than or equal to an operation cost coefficient threshold value, judging that the operation cost of the corresponding water sump is high, marking the corresponding water sump as a high-cost water sump, and if the operation cost coefficient FYI in the water sump is less than the operation cost coefficient threshold value, judging that the operation cost of the corresponding water sump is low, and marking the corresponding water sump as a low-cost water sump; and then acquiring a charging standard of the region of the water sump and the number of users in the whole day period, acquiring the electricity consumption number SJp of the whole day period through a formula, marking the time period with the lowest electricity consumption number SJp as an operation time period, and then operating the high-cost water sump according to the operation time period.

The above formulas are all formulas with dimensions removed and numerical values calculated, the formulas are formulas with a large amount of data collected for software simulation to obtain the latest real situation, and preset parameters in the formulas are set by those skilled in the art according to the actual situation.

The foregoing is merely illustrative of the structures of this invention and various modifications, additions and substitutions for those skilled in the art can be made to the described embodiments without departing from the scope of the invention or from the scope of the invention as defined in the accompanying claims.

Claims (4)

1. The remote control system of the water pump is characterized by comprising a cloud control platform, a water sump detection unit, an energy-saving regulation unit, a water pump detection unit, a conversion regulation unit, a registration login unit and a database;

the energy-saving adjusting unit is used for adjusting the operation of the water pump, and the specific adjusting process is as follows:

step SS1: equally dividing a water bin into a plurality of water level segments, marking the water level segments with positions o, o=1, 2, … …, m and m as positive integers, then acquiring the water descending rate of each hour corresponding to the water level segments, acquiring the water discharge amount of the corresponding water bin according to the water descending rate and the working time length of the whole day, and marking the water discharge amount of the corresponding water bin as FSi;

step SS2: obtaining a supply current corresponding to a water pump in a water sump, marking the supply current as DLi, marking the voltage as 220V according to a supply voltage standard, obtaining an operation power corresponding to the water pump in the water sump through the supply current and the supply voltage, and marking the operation power of the water pump in the water sump as GLi;

step SS3: the dimensionality removal is carried out, the value of the dimensionality removal is obtained through a formula FYI=beta (FSi multiplied by b1+GLi multiplied by b 2), and the running cost coefficient FYI in the water sump is obtained, wherein b1 and b2 are both proportional coefficients, b1 is more than b2 is more than 0, beta is an error correction factor, and the value is 2.362214; the running cost coefficient FYi in the sump is then compared to a running cost coefficient threshold value: if the running cost coefficient FYI in the water sump is more than or equal to the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is high, marking the corresponding water sump as a high-cost water sump, and if the running cost coefficient FYI in the water sump is less than the running cost coefficient threshold value, judging that the running cost of the corresponding water sump is low, and marking the corresponding water sump as a low-cost water sump;

step SS4: then acquiring a charging standard of a region of the water sump and the number of users of the water sump in the whole day period, marking the charging standard of the water sump in the whole day period and the number of users of the water sump in SFp and YDp, marking the water sump in the whole day period as p, p=1, 2, … … and 24, and then dimensionalizing the values to acquire an electricity utilization number SJp of the water sump in the whole day period through a formula SJp =alpha (SFp ×b3+ YDp ×b4), wherein b3 and b4 are proportionality coefficients, and b3 is larger than b4 is larger than 0;

step SS5: the lowest period of time for which the electricity consumption number SJp is the operating period is marked, and then the high-cost water sump is operated according to the operating period.

2. The remote control system of a water pump according to claim 1, wherein the water sump detection unit is configured to analyze parameter information of the water sump to detect the water sump, the parameter information of the water sump includes water level data, flow data and pressure data, the water sump is marked as i, i=1, 2, … …, n, n is a positive integer, and a specific analysis detection process is as follows: the method comprises the steps of obtaining a distance difference value between the water level in the water sump and the full water level, an average flowing speed of water in the water sump and an average water pressure of each area in the water sump, obtaining a detection coefficient Xi of the water sump through a formula by taking the value of the distance difference value, the average flowing speed and the average water pressure, and comparing the detection coefficient Xi with a detection coefficient threshold of the water sump.

3. The remote control system of a water pump according to claim 1, wherein the water pump detection unit is configured to analyze water pump operation data in the water sump to detect the water pump, the water pump operation data is noise data, interval data, and temperature data, and the water pump is marked as j, j=1, 2, … …, f, f is a positive integer, and the specific analysis detection process is as follows:

step T1: acquiring a noise decibel value generated by a water pump in a water sump when in operation, and marking the noise decibel value generated by the water pump in the water sump when in operation as FBZf;

step T2: acquiring the buffer time when the water pump in the water sump is started, and marking the buffer time when the water pump in the water sump is started as HCSf;

step T3: acquiring a temperature value of the interior of the equipment when the water pump in the water sump operates, and marking the temperature value of the interior of the equipment when the water pump in the water sump operates as WDZf;

step T4: removing dimension and taking its value through formula

Acquiring a detection coefficient JCf of a water pump in a water sump, wherein c1, c2 and c3 are proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, and e is a natural constant;

step T5: comparing the detection coefficient JCf of the water pump in the water sump with a detection coefficient threshold of the water pump:

if the detection coefficient JCf of the water pump in the water bin is more than or equal to the detection coefficient threshold of the water pump, judging that the water pump in the corresponding water bin is abnormal in operation, generating a water pump abnormal signal and sending the water pump abnormal signal to the cloud control platform, and after the cloud control platform receives the water pump abnormal signal, generating a water pump maintenance signal and sending the water pump maintenance signal to a mobile phone terminal of an operator;

if the detection coefficient JCf of the water pump in the water bin is smaller than the detection coefficient threshold value of the water pump, the water pump in the corresponding water bin is judged to run normally, a water pump normal signal is generated and sent to the cloud control platform, and the cloud control platform sends the water pump normal signal to the mobile phone terminal of the manager.

4. The remote control system of a water pump according to claim 1, wherein the conversion adjustment unit is configured to analyze control data of the water pump in the sump, so as to perform conversion adjustment on control of the water pump, and a specific analysis and detection process is as follows: the method comprises the steps of obtaining the average start-stop times of the water pump in the running process, the average use times of the water pump pipeline in the whole day and the average flow of the water pump pipeline in each hour, taking the values of the average start-stop times, the average use times of the water pump pipeline in the whole day and the average flow of the water pump pipeline in each hour, obtaining the water pump regulating coefficient Xf in the water sump through a formula by taking the values of the average start-stop times, the average use times of the water pump pipeline in the whole day and the average flow of the water pump pipeline in each hour, and comparing the water pump regulating coefficient Xf in the water sump with a water pump regulating coefficient threshold.