CN116465459A - Intelligent tooth washing device operation control system - Google Patents

Abstract

The invention belongs to the field of tooth flushers, relates to a data analysis technology, and is used for solving the problem that an intelligent tooth flusher operation control system in the prior art cannot optimize a charging mode of the intelligent tooth flusher operation control system, in particular to an intelligent tooth flusher operation control system, wherein an operation control platform is in communication connection with a charging monitoring module, an operation monitoring module, a function auxiliary module, a controller, a display module and a storage module; the intelligent tooth-cleaning device monitors and analyzes the running state of the intelligent tooth-cleaning device, timely gives an early warning when the running abnormality occurs to the monitored object, and timely cuts off the power supply line of the monitored object through the controller to prevent the monitored object from running in the abnormal state for a long time to cause more serious faults.

Description

Intelligent tooth washing device operation control system

Technical Field

The invention belongs to the field of tooth flushers, relates to a data analysis technology, and particularly relates to an intelligent tooth flusher operation control system.

Background

The tooth cleaning device is an auxiliary tool for cleaning the oral cavity, and is used for cleaning teeth and tooth gaps in a pulse water flow impact mode, and the cleaning effect of the tooth cleaning device is mainly realized by using the impact force of high-speed water columns sprayed under a certain pressure;

the intelligent tooth-rinsing device operation control system in the prior art can only realize basic functions such as electric quantity early warning and water quantity early warning, but can not effectively monitor the use state of the intelligent tooth-rinsing device, so that the early warning can not be timely carried out when the intelligent tooth-rinsing device operates abnormally, and meanwhile, the intelligent tooth-rinsing device operation control system in the prior art can not optimize the charging mode, so that the optimized charging parameters can not be set for the intelligent tooth-rinsing device;

aiming at the technical problems, the application provides a solution.

Disclosure of Invention

The invention aims to provide an intelligent tooth-rinsing device operation control system which is used for solving the problem that an intelligent tooth-rinsing device operation control system in the prior art cannot optimize a charging mode of the intelligent tooth-rinsing device operation control system.

The technical problems to be solved by the invention are as follows: how to provide an intelligent tooth rinse operation control system which can optimize the charging mode thereof.

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

an intelligent tooth-rinsing device operation control system comprises an operation control platform, wherein the operation control platform is in communication connection with a charging monitoring module, an operation monitoring module, a function auxiliary module, a controller, a display module and a storage module;

the operation monitoring module is used for monitoring and analyzing the operation state of the intelligent tooth cleaning device and obtaining an operation coefficient of a monitored object, judging whether the operation state of the monitored object meets the requirement or not according to the numerical value of the operation coefficient, sending an operation abnormal signal to the operation control platform when the operation state of the monitored object does not meet the requirement, sending the operation abnormal signal to the controller after the operation control platform receives the operation abnormal signal, and cutting off a power supply line of the monitored object after the controller receives the operation abnormal signal;

the display module comprises a water quantity early warning signal lamp and an electric quantity early warning signal lamp;

the charging monitoring module is used for monitoring and analyzing the charging state of the intelligent tooth washer to obtain the charging coefficient of a monitored object, and performing optimization analysis at the end time of a monitoring period;

the function auxiliary module comprises an electric quantity auxiliary unit and a water quantity auxiliary unit; the electric quantity auxiliary unit is used for monitoring the residual electric quantity of the monitored object; the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object.

As a preferred embodiment of the invention, the specific process of monitoring and analyzing the operation state of the intelligent tooth irrigator by the operation monitoring module comprises the following steps: generating a monitoring period, marking the intelligent tooth flusher as a monitoring object, and acquiring vibration data, noise data and water pressure data of the monitoring object when the monitoring object runs; obtaining an operation coefficient of the monitoring object by carrying out numerical calculation on vibration data, noise data and water pressure data of the monitoring object; the operation threshold value is obtained through the storage module, the operation coefficient of the monitoring object is compared with the operation threshold value, and whether the operation state of the monitoring object meets the requirement or not is judged according to the comparison result.

As a preferred embodiment of the present invention, the vibration data is a vibration frequency value of the monitored object within the last L1 seconds, the noise data is a noise decibel value generated when the monitored object operates, and the process of acquiring the water pressure data includes: and acquiring a water pressure value of the nozzle and an operation gear of the monitoring object during operation of the monitoring object, acquiring a corresponding water pressure range in the storage module according to the operation gear, marking an average value of a maximum value and a minimum value of the water pressure range as a water pressure standard value, and marking an absolute value of a difference value between the water pressure value of the nozzle and the water pressure standard value as water pressure data.

As a preferred embodiment of the present invention, the specific process of comparing the operation coefficient of the monitoring object with the operation threshold value includes: if the operation coefficient is smaller than the operation threshold value, judging that the operation state of the monitored object meets the requirement, and sending an operation abnormal signal to the operation control platform by the operation monitoring module; if the operation coefficient is greater than or equal to the operation threshold, the operation state of the monitored object is judged to be not satisfied, and the operation monitoring module sends an operation normal signal to the operation control platform.

As a preferred embodiment of the present invention, the charging monitoring module is further configured to switch and control a charging mode of the intelligent tooth irrigator: the trickle range and the constant voltage range are obtained through the storage module, and when a monitored object is charged, a numerical value is randomly selected from the trickle range and the constant voltage range to serve as a trickle value and a constant voltage value respectively; the method comprises the steps of detecting the charge quantity of a monitored object in real time, firstly adopting a trickle charge mode to charge the monitored object, switching the charge mode into a constant voltage charge mode when the charge quantity of the monitored object reaches a trickle value, and switching the charge mode into the trickle charge mode again when the charge quantity of the monitored object reaches the constant voltage value.

As a preferred embodiment of the present invention, the process of acquiring the charging coefficient of the monitoring object includes: after the monitoring object is charged, acquiring working hour data, use data, charging time data and abnormal data of the monitoring object; the charging coefficient of the monitoring object is obtained by performing numerical calculation on the man-hour data, the usage data, the charging time data and the abnormal data of the monitoring object.

As a preferred embodiment of the present invention, the process of acquiring man-hour data of a monitoring object includes: marking the time when the monitoring object finishes charging as working starting time, marking the time when the monitoring object charges next time as working junction time, forming a working period by the working starting time and the working junction time, and marking the running total duration of the monitoring object in the working period as working time data; the use data is the working times of the monitoring object in the working period; the charging time data is the charging time length of the monitoring object for charging; the abnormal data is the number of times that the monitoring object has abnormal operation in the monitoring period.

As a preferred embodiment of the present invention, the specific process of performing the optimization analysis at the end of the monitoring period includes: acquiring all charging coefficients of a monitoring object in a monitoring period, sequencing the charging coefficients from high to low, respectively constructing a trickle set and a constant voltage set by trickle values and constant voltage values corresponding to the first L2 charging coefficients in the sequencing, forming a new trickle range by an element with the smallest value and an element with the largest value in the trickle set, forming a new constant voltage range by an element with the smallest value and an element with the largest value in the constant voltage set, transmitting the new trickle range and the new constant voltage range to a storage module, and respectively replacing the trickle range and the constant voltage range in the storage module.

As a preferred embodiment of the present invention, the specific process of monitoring the remaining power of the monitored object by the power assisting unit includes: the power supply system comprises a storage module, a power auxiliary unit, an operation control platform, a display module and a power control module, wherein the storage module is used for acquiring a power threshold, when the residual power reaches the power threshold, the power auxiliary unit is used for sending a power early-warning signal to the operation control platform, the operation control platform is used for sending the power early-warning signal to the display module after receiving the power early-warning signal, and the display module is used for controlling the power early-warning signal lamp to be bright red after receiving the power early-warning signal.

As a preferred embodiment of the invention, the specific process of monitoring the residual water quantity of the monitored object by the water quantity auxiliary unit comprises the steps of acquiring a water quantity threshold value through the storage module, sending a water quantity early warning signal to the operation control platform when the residual water quantity reaches the water quantity threshold value, sending the water quantity early warning signal to the display module after the operation control platform receives the water quantity early warning signal, and controlling the water quantity early warning signal to be bright red after the display module receives the water quantity early warning signal.

As a preferred embodiment of the present invention, the trickle charge mode of operation includes: charging by adopting constant current as a monitoring object; the constant voltage charging mode comprises the following working processes: and charging the monitoring object by adopting constant voltage.

The working method of the intelligent tooth-rinsing device operation control system comprises the following steps:

step one: monitoring and analyzing the running state of the intelligent tooth washer: obtaining vibration data, noise data and water pressure data of a monitoring object, performing numerical calculation to obtain an operation coefficient, and judging whether the operation state of the monitoring object meets the requirement or not according to the numerical value of the operation coefficient;

step two: monitoring and analyzing the charging state of the intelligent tooth washer: obtaining a trickle range and a constant voltage range through a storage module, obtaining a charging coefficient of a monitoring object when the monitoring object is charged, and carrying out optimization analysis at the end time of a monitoring period;

step three: monitoring the residual electric quantity of the monitored object through an electric quantity auxiliary unit, and performing electric quantity early warning when the residual electric quantity does not meet the requirement;

step four: the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object, and water quantity early warning is carried out when the residual water quantity does not meet the requirement.

The invention has the following beneficial effects:

1. the intelligent tooth cleaning device can monitor and analyze the operation state of the intelligent tooth cleaning device through the operation monitoring module, and the operation coefficient is obtained through comprehensive calculation of a plurality of operation parameters of a monitored object, so that the operation state of the monitored object is fed back according to the operation coefficient, early warning is timely carried out when an abnormal operation phenomenon occurs to the monitored object, and a power supply circuit of the monitored object is timely cut off through a controller, so that the monitored object is prevented from running in the abnormal state for a long time to cause more serious faults; the charging mode of the intelligent tooth washer can be automatically switched and controlled through the charging monitoring module, constant-current charging is adopted in the initial stage, the rapid and stable charging current is guaranteed, constant-voltage charging is adopted in the middle stage, the safety of a battery is protected, trickle charging is adopted in the end stage, a charging channel is turned off after a charging set value is reached, and the charging safety is improved while the charging efficiency is guaranteed;

2. the invention can also optimize and analyze the charging parameters of the intelligent tooth-cleaning device through the charging monitoring module, and obtain the charging coefficient through analyzing the use state of the intelligent tooth-cleaning device after charging, thereby generating a new trickle range and a new constant voltage range by combining the numerical value of the charging coefficient and the trickle value and the constant voltage value selected during charging, and optimizing the charging parameters at the end time of each monitoring period, so as to continuously improve the charging state of the intelligent tooth-cleaning device during the subsequent charging; and can assist the early warning to intelligent tooth washer through function auxiliary module, in time carry out the early warning when surplus water yield or surplus electric quantity do not satisfy the requirement, remind the user to charge or add water, prevent that water yield or electric quantity from using up and leading to intelligent tooth washer operation to suspend.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive effort to a person skilled in the art.

FIG. 1 is a system block diagram of a first embodiment of the present invention;

fig. 2 is a flowchart of a method according to a second embodiment of the 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, but 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.

Example 1

As shown in fig. 1, the intelligent tooth cleaning device operation control system comprises an operation control platform, wherein the operation control platform is in communication connection with a charging monitoring module, an operation monitoring module, a function auxiliary module, a controller, a display module and a storage module.

The operation monitoring module is used for monitoring and analyzing the operation state of the intelligent tooth washer: generating a monitoring period, marking the intelligent tooth washer as a monitoring object, acquiring vibration data ZD, noise data ZS and water pressure data SY of the monitoring object when the monitoring object is in operation, wherein the vibration data ZD is a vibration frequency value of the monitoring object in the last L1 seconds, the noise data ZS is a noise decibel value generated when the monitoring object is in operation, and the acquisition process of the water pressure data SY comprises the following steps: acquiring a water pressure value of a nozzle and an operation gear of a monitoring object during operation of the monitoring object, acquiring a corresponding water pressure range in a storage module according to the operation gear, marking an average value of a maximum value and a minimum value of the water pressure range as a water pressure standard value, and marking an absolute value of a difference value between the water pressure value of the nozzle and the water pressure standard value as water pressure data SY; obtaining an operation coefficient YX of the monitoring object through a formula YX=α1xZD+α2xZS+α3xSY, wherein the operation coefficient is a numerical value reflecting the abnormal operation probability of the monitoring object, and the larger the numerical value of the operation coefficient is, the higher the abnormal operation probability of the monitoring object is; wherein α1, α2, and α3 are proportionality coefficients, and α3 > α2 > α1 > 1; the operation threshold value YXmax is obtained through the storage module, and the operation coefficient YX of the monitored object is compared with the operation threshold value YXmax: if the operation coefficient YX is smaller than the operation threshold YXmax, judging that the operation state of the monitoring object meets the requirement, sending an operation abnormal signal to the operation control platform by the operation monitoring module, sending the operation abnormal signal to the controller after the operation control platform receives the operation abnormal signal, and cutting off a power supply line of the monitoring object after the controller receives the operation abnormal signal; if the operation coefficient YX is greater than or equal to the operation threshold YXmax, judging that the operation state of the monitored object does not meet the requirement, and sending an operation normal signal to an operation control platform by the operation monitoring module; the intelligent tooth cleaning device is used for monitoring and analyzing the running state of the intelligent tooth cleaning device, and the running coefficients are obtained by comprehensively calculating a plurality of running parameters of a monitored object, so that the running state of the monitored object is fed back according to the running coefficients, early warning is timely carried out when the running abnormality phenomenon occurs to the monitored object, and a power supply line of the monitored object is timely cut off through a controller, so that the monitored object is prevented from running in the abnormal state for a long time to cause more serious faults.

The display module comprises a water quantity early warning signal lamp and an electric quantity early warning signal lamp.

The charging monitoring module is used for monitoring and analyzing the charging state of the intelligent tooth washer: the trickle range and the constant voltage range are obtained through the storage module, and when a monitored object is charged, a numerical value is randomly selected from the trickle range and the constant voltage range to serve as a trickle value and a constant voltage value respectively; detecting the charge quantity of a monitored object in real time, firstly adopting a trickle charge mode as the monitored object to charge, switching the charge mode into a constant voltage charge mode when the charge quantity of the monitored object reaches a trickle value, and switching the charge mode into the trickle charge mode again when the charge quantity of the monitored object reaches a constant voltage value; the charging mode of the intelligent tooth washer is automatically switched and controlled, constant current charging is adopted in the initial stage, the rapid and stable charging current is guaranteed, constant voltage charging is adopted in the middle stage, the safety of a battery is protected, trickle charging is adopted in the end stage, a charging channel is turned off after a charging set value is reached, and the charging safety is improved while the charging efficiency is guaranteed; after the monitoring object is charged, acquiring working hour data GS, use data SY, charging time data CS and abnormal data YC of the monitoring object; the process of acquiring the man-hour data GS of the monitoring object includes: marking the time when the monitoring object finishes charging as working starting time, marking the time when the monitoring object charges next time as working junction time, forming a working period by the working starting time and the working junction time, and marking the running total duration of the monitoring object in the working period as working time data GS; the usage data SY is the number of times of the monitoring object works in the working period; the charging time data CS is the charging time length of the current charging of the monitoring object; the abnormal data YC is the number of times that the monitoring object has abnormal operation in the monitoring period; obtaining a charging coefficient CD of the monitored object according to a formula CD= (beta 1 x GS+beta 2 x SY)/(beta 3 x CS+beta 4 x YC), wherein the charging coefficient is a numerical value reflecting the using state of the monitored object after charging, and the larger the numerical value of the charging coefficient is, the better the using state of the monitored object after charging is indicated; wherein β1, β2, β3 and β4 are all scaling factors, and β4 > β3 > β2 > β1 > 1; and (3) carrying out optimization analysis at the end time of the monitoring period: acquiring all charging coefficients of a monitoring object in a monitoring period, sequencing the charging coefficients from high to low, respectively constructing trickle sets and constant voltage sets by trickle values and constant voltage values corresponding to the first L2 charging coefficients in sequencing, wherein L1 and L2 are constant values, and specific numerical values of L1 and L2 are set by a manager; the method comprises the steps that a new trickle range is formed by an element with the smallest value in a trickle set and an element with the largest value, a new constant voltage range is formed by an element with the smallest value in a constant voltage set and an element with the largest value, the new trickle range and the new constant voltage range are sent to a storage module, and the trickle range and the constant voltage range in the storage module are replaced respectively; the method comprises the steps of carrying out optimization analysis on charging parameters of the intelligent tooth flushing device, and obtaining a charging coefficient by analyzing the use state of the intelligent tooth flushing device after charging, so that a new trickle range and a new constant voltage range are generated by combining the numerical value of the charging coefficient and the trickle value and the constant voltage value selected during charging, and the charging parameters are optimized at the end time of each monitoring period, so that the charging state of the intelligent tooth flushing device during subsequent charging is continuously improved.

The trickle charge mode of operation includes: charging by adopting constant current as a monitoring object; the constant voltage charging mode comprises the following working processes: and charging the monitoring object by adopting constant voltage.

The function auxiliary module comprises an electric quantity auxiliary unit and an electric quantity auxiliary unit, wherein the electric quantity auxiliary unit is used for monitoring the residual electric quantity of a monitored object, an electric quantity threshold value is obtained through the storage module, when the residual electric quantity reaches the electric quantity threshold value, the electric quantity auxiliary unit sends an electric quantity early warning signal to the operation control platform, the operation control platform sends the electric quantity early warning signal to the display module after receiving the electric quantity early warning signal, and the display module controls the electric quantity early warning signal lamp to be bright red after receiving the electric quantity early warning signal; the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object, the water quantity threshold value is obtained through the storage module, when the residual water quantity reaches the water quantity threshold value, the water quantity auxiliary unit sends a water quantity early warning signal to the operation control platform, the operation control platform sends the water quantity early warning signal to the display module after receiving the water quantity early warning signal, and the display module controls the water quantity early warning signal lamp to be bright red after receiving the water quantity early warning signal; auxiliary early warning is carried out on the intelligent tooth washer, and early warning is carried out in time when the residual water quantity or the residual electric quantity does not meet the requirement, so that a user is reminded to charge or add water, and the intelligent tooth washer is prevented from being stopped due to water quantity or electric quantity exhaustion.

Example two

As shown in fig. 2, an intelligent tooth rinse operation control method includes the following steps:

step one: monitoring and analyzing the running state of the intelligent tooth washer: obtaining vibration data, noise data and water pressure data of a monitoring object, performing numerical calculation to obtain an operation coefficient, and judging whether the operation state of the monitoring object meets the requirement or not according to the numerical value of the operation coefficient;

step two: monitoring and analyzing the charging state of the intelligent tooth washer: obtaining a trickle range and a constant voltage range through a storage module, obtaining a charging coefficient of a monitoring object when the monitoring object is charged, and carrying out optimization analysis at the end time of a monitoring period;

step three: monitoring the residual electric quantity of the monitored object through an electric quantity auxiliary unit, and performing electric quantity early warning when the residual electric quantity does not meet the requirement;

step four: the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object, and water quantity early warning is carried out when the residual water quantity does not meet the requirement.

An intelligent tooth-rinsing device operation control system is used for obtaining vibration data, noise data and water pressure data of a monitored object and performing numerical calculation to obtain an operation coefficient, and judging whether the operation state of the monitored object meets the requirement or not according to the numerical value of the operation coefficient; obtaining a trickle range and a constant voltage range through a storage module, obtaining a charging coefficient of a monitoring object when the monitoring object is charged, and carrying out optimization analysis at the end time of a monitoring period; monitoring the residual electric quantity of the monitored object through an electric quantity auxiliary unit, and performing electric quantity early warning when the residual electric quantity does not meet the requirement; the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object, and water quantity early warning is carried out when the residual water quantity does not meet the requirement.

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.

The formulas are all formulas obtained by collecting a large amount of data for software simulation and selecting a formula close to a true value, and coefficients in the formulas are set by a person skilled in the art according to actual conditions; such as: the formula yx=α1×zd+α2×zs+α3×sy; collecting a plurality of groups of sample data by a person skilled in the art and setting a corresponding operation coefficient for each group of sample data; substituting the set operation coefficient and the collected sample data into a formula, forming a ternary one-time equation set by any three formulas, screening the calculated coefficient, and taking an average value to obtain values of alpha 1, alpha 2 and alpha 3 which are 3.74, 2.97 and 2.65 respectively;

the size of the coefficient is a specific numerical value obtained by quantizing each parameter, so that the subsequent comparison is convenient, and the size of the coefficient depends on the number of sample data and the corresponding operation coefficient is preliminarily set for each group of sample data by a person skilled in the art; as long as the proportional relation between the parameter and the quantized value is not affected, for example, the operation coefficient is in direct proportion to the value of the water pressure data.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (12)

1. The intelligent tooth-rinsing device operation control system is characterized by comprising an operation control platform, wherein the operation control platform is in communication connection with a charging monitoring module, an operation monitoring module, a function auxiliary module, a controller, a display module and a storage module;

the operation monitoring module is used for monitoring and analyzing the operation state of the intelligent tooth cleaning device and obtaining an operation coefficient of a monitored object, judging whether the operation state of the monitored object meets the requirement or not according to the numerical value of the operation coefficient, sending an operation abnormal signal to the operation control platform when the operation state of the monitored object does not meet the requirement, sending the operation abnormal signal to the controller after the operation control platform receives the operation abnormal signal, and cutting off a power supply line of the monitored object after the controller receives the operation abnormal signal;

the display module comprises a water quantity early warning signal lamp and an electric quantity early warning signal lamp;

the charging monitoring module is used for monitoring and analyzing the charging state of the intelligent tooth washer to obtain the charging coefficient of a monitored object, and performing optimization analysis at the end time of a monitoring period;

the function auxiliary module comprises an electric quantity auxiliary unit and a water quantity auxiliary unit; the electric quantity auxiliary unit is used for monitoring the residual electric quantity of the monitored object; the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object.

2. The intelligent dental appliance operation control system of claim 1, wherein the operation monitoring module monitors and analyzes the operation state of the intelligent dental appliance, comprising: generating a monitoring period, marking the intelligent tooth flusher as a monitoring object, and acquiring vibration data, noise data and water pressure data of the monitoring object when the monitoring object runs; obtaining an operation coefficient of the monitoring object by carrying out numerical calculation on vibration data, noise data and water pressure data of the monitoring object; the operation threshold value is obtained through the storage module, the operation coefficient of the monitoring object is compared with the operation threshold value, and whether the operation state of the monitoring object meets the requirement or not is judged according to the comparison result.

3. The intelligent dental irrigator operation control system according to claim 2, wherein the vibration data is a vibration frequency value of the monitored object within the last L1 seconds, the noise data is a noise decibel value generated when the monitored object operates, and the water pressure data acquiring process includes: and acquiring a water pressure value of the nozzle and an operation gear of the monitoring object during operation of the monitoring object, acquiring a corresponding water pressure range in the storage module according to the operation gear, marking an average value of a maximum value and a minimum value of the water pressure range as a water pressure standard value, and marking an absolute value of a difference value between the water pressure value of the nozzle and the water pressure standard value as water pressure data.

4. The intelligent dental appliance operation control system of claim 2, wherein the specific process of comparing the operational coefficient of the monitored subject to the operational threshold comprises: if the operation coefficient is smaller than the operation threshold value, judging that the operation state of the monitored object meets the requirement, and sending an operation abnormal signal to the operation control platform by the operation monitoring module; if the operation coefficient is greater than or equal to the operation threshold, the operation state of the monitored object is judged to be not satisfied, and the operation monitoring module sends an operation normal signal to the operation control platform.

5. The intelligent dental appliance operation control system of claim 1, wherein the charge monitor module is further configured to switch control of a charging mode of the intelligent dental appliance: the trickle range and the constant voltage range are obtained through the storage module, and when a monitored object is charged, a numerical value is randomly selected from the trickle range and the constant voltage range to serve as a trickle value and a constant voltage value respectively; the method comprises the steps of detecting the charge quantity of a monitored object in real time, firstly adopting a trickle charge mode to charge the monitored object, switching the charge mode into a constant voltage charge mode when the charge quantity of the monitored object reaches a trickle value, and switching the charge mode into the trickle charge mode again when the charge quantity of the monitored object reaches the constant voltage value.

6. The intelligent dental appliance operation control system of claim 5, wherein the process of obtaining the charging factor of the monitored subject comprises: after the monitoring object is charged, acquiring working hour data, use data, charging time data and abnormal data of the monitoring object; the charging coefficient of the monitoring object is obtained by performing numerical calculation on the man-hour data, the usage data, the charging time data and the abnormal data of the monitoring object.

7. The intelligent dental rinse operation control system according to claim 6, wherein the process of acquiring the man-hour data of the monitored subject comprises: marking the time when the monitoring object finishes charging as working starting time, marking the time when the monitoring object charges next time as working junction time, forming a working period by the working starting time and the working junction time, and marking the running total duration of the monitoring object in the working period as working time data; the use data is the working times of the monitoring object in the working period; the charging time data is the charging time length of the monitoring object for charging; the abnormal data is the number of times that the monitoring object has abnormal operation in the monitoring period.

8. The intelligent dental rinse operation control system of claim 7, wherein the specific process of performing the optimization analysis at the end of the monitoring period comprises: acquiring all charging coefficients of a monitoring object in a monitoring period, sequencing the charging coefficients from high to low, respectively constructing a trickle set and a constant voltage set by trickle values and constant voltage values corresponding to the first L2 charging coefficients in the sequencing, forming a new trickle range by an element with the smallest value and an element with the largest value in the trickle set, forming a new constant voltage range by an element with the smallest value and an element with the largest value in the constant voltage set, transmitting the new trickle range and the new constant voltage range to a storage module, and respectively replacing the trickle range and the constant voltage range in the storage module.

9. The intelligent dental appliance operation control system according to claim 1, wherein the specific process of monitoring the remaining power of the monitored subject by the power assisting unit comprises: the power supply system comprises a storage module, a power auxiliary unit, an operation control platform, a display module and a power control module, wherein the storage module is used for acquiring a power threshold, when the residual power reaches the power threshold, the power auxiliary unit is used for sending a power early-warning signal to the operation control platform, the operation control platform is used for sending the power early-warning signal to the display module after receiving the power early-warning signal, and the display module is used for controlling the power early-warning signal lamp to be bright red after receiving the power early-warning signal.

10. The intelligent tooth-rinsing device operation control system according to claim 1, wherein the specific process of the water quantity auxiliary unit for monitoring the residual water quantity of the monitored object comprises the steps of obtaining a water quantity threshold value through the storage module, sending a water quantity early warning signal to the operation control platform when the residual water quantity reaches the water quantity threshold value, sending the water quantity early warning signal to the display module after the operation control platform receives the water quantity early warning signal, and controlling the water quantity early warning signal lamp to be bright red after the display module receives the water quantity early warning signal.

11. The intelligent rinse operation control system of claim 5, wherein the trickle charge mode of operation comprises: charging by adopting constant current as a monitoring object; the constant voltage charging mode comprises the following working processes: and charging the monitoring object by adopting constant voltage.

12. The method of operation of an intelligent dental rinse operation control system of any of claims 1-11, comprising the steps of:

step one: monitoring and analyzing the running state of the intelligent tooth washer: obtaining vibration data, noise data and water pressure data of a monitoring object, performing numerical calculation to obtain an operation coefficient, and judging whether the operation state of the monitoring object meets the requirement or not according to the numerical value of the operation coefficient;

step two: monitoring and analyzing the charging state of the intelligent tooth washer: obtaining a trickle range and a constant voltage range through a storage module, obtaining a charging coefficient of a monitoring object when the monitoring object is charged, and carrying out optimization analysis at the end time of a monitoring period;

step three: monitoring the residual electric quantity of the monitored object through an electric quantity auxiliary unit, and performing electric quantity early warning when the residual electric quantity does not meet the requirement;

step four: the water quantity auxiliary unit is used for monitoring the residual water quantity of the monitored object, and water quantity early warning is carried out when the residual water quantity does not meet the requirement.