CN113844972B - Method and system for monitoring sanitary environment in elevator car and storage medium - Google Patents

Abstract

The application relates to a method, a system and a storage medium for monitoring sanitation environment in an elevator car, relates to the technical field of elevator cars, and solves the problems that the treatment opportunity of integral pollutants is uncontrollable, the experience of passengers is influenced, and comprises the following steps: based on the influence degree of the pollutants, the set finishing time of the pollutants with the corresponding influence degree, the tools and the positions of the pollutants with the corresponding influence degree, the working state of a pollutant treating person, the current position and the probability of carrying the corresponding tool with the pollutant treating person, the pollutant treating person with the shortest time consumption for reaching the elevator car with the pollutants, which is adaptive to the influence degree of the current pollutants and carries the corresponding tool, is analyzed and determined to serve as the pollutant treating person for confirming the notification, and the notification information is sent to the terminal of the pollutant treating person for confirming the notification. The application has the following effects: the pollutants are convenient to be treated in time, and the influence on the personnel taking the elevator is reduced.

Description

Method and system for monitoring sanitary environment in elevator car and storage medium

Technical Field

The application relates to the technical field of elevator cars, in particular to a method and a system for monitoring sanitation environment in an elevator car and a storage medium.

Background

The elevator is an important component of public facilities, the elevator car is a box-shaped space used for bearing and transporting people and materials, the elevator car generally comprises a car bottom, a car wall, a car top, a car door and other main components, the sanitation environment in the elevator car is related to the vital interests of users, when pollutants (such as animal excrement, human urine, drunk people vomiting and the like) appear in the elevator car, the use environment in the elevator car can be seriously influenced, and great inconvenience is brought to other passengers.

At present, a special monitoring person monitors the service environment in the elevator car through a camera arranged in the elevator car in a monitoring room, and when the service environment is greatly influenced by pollutants, a pollutant treating person is informed to go to the field for treatment at random.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: whether the use environment is greatly influenced by pollutants depends on subjective judgment of monitoring personnel, the influence degree of the pollutants depends on the pollutants and the tolerance of people to the corresponding pollutants, so that the pollutants are easily treated too early or too late when being informed, and the pollutant treatment opportunity is also uncontrollable due to the randomness of the informed pollutant treatment personnel, so that the treatment opportunity of the pollutants is uncontrollable, the treatment opportunity of the whole pollutants is uncontrollable, and the experience of passengers is influenced.

Disclosure of Invention

In order to facilitate timely treatment of pollutants and reduce influence on elevator passengers, the application provides a method and a system for monitoring the sanitary environment in an elevator car and a storage medium.

In a first aspect, the application provides a method for monitoring a sanitary environment in an elevator car, which adopts the following technical scheme:

a method of monitoring a sanitary environment within an elevator car, comprising:

acquiring position information, pollutant type information and pollutant coverage area information of pollutants in an elevator car;

analyzing and confirming the influence degree of the pollutants based on the position information, the pollutant type information and the pollutant coverage area information of the pollutants in the elevator, the distribution proportion data of the age groups of the people taking the elevator at the current time and the tolerance of the people of different age groups to the pollutants, wherein the influence degree of the pollutants can be classified into serious, general and slight;

based on the influence degree of the pollutants, the set finishing time of the pollutants with the corresponding influence degree, the tools and the positions of the pollutants with the corresponding influence degree, the working state of a pollutant treating person, the current position and the probability of carrying the corresponding tool with the pollutant treating person, the pollutant treating person with the shortest time consumption for reaching the elevator car with the pollutants, which is adaptive to the influence degree of the current pollutants and carries the corresponding tool, is analyzed and determined to serve as the pollutant treating person for confirming the notification, and the notification information is sent to the terminal of the pollutant treating person for confirming the notification.

By adopting the technical scheme, the influence degree of the pollutants is comprehensively judged by not only considering the self dimensions of the position information of the pollutants, the pollutant type information and the pollutant coverage area information, but also combining the age group distribution proportion data of the people taking the elevator at the current time and the personnel information of the tolerance of the people at different age groups to the pollutants, compared with the original single dimension, the influence degree of the pollutants is determined by considering the self dimensions of the pollutants, the influence degree of the pollutants can be more reasonably defined, and on the basis of defining the influence degree of the pollutants, the most suitable people for treating the pollutants can be analyzed and informed so as to be convenient for the pollutants to be treated in time by combining the tool and the position required to be applied by pollutant treatment, the age group distribution proportion data of the people taking the elevator at the current time and the tolerance of the people at different age groups to the pollutants, the influence on the personnel taking the elevator is reduced.

Optionally, the obtaining of the age group distribution ratio data of the persons who take the elevator at the current time comprises:

acquiring distribution proportion data of different age groups of elevator passengers in different historical time periods, wherein the age groups of the elevator passengers are divided as follows: the childhood period is as follows: 0 to 6 years old; juvenile stage: from 7 to 17 years old; young age period: 18 to 40 years old; and (4) middle-aged period: age 41 to 65 years old; old age: after age 66 years;

and carrying out statistical analysis to obtain history and integral distribution proportion data of different age groups in elevator taking personnel who belong to the same time period at present, and integral distribution proportion data of different age groups in elevator taking personnel who belong to the same time period at the nearest time, and taking the average value of the history and the integral distribution proportion data as the distribution proportion data of different age groups in elevator taking personnel at the present time period.

By adopting the technical scheme, the distribution proportion data of different age groups of the elevator taking personnel in the current time period can be effectively analyzed and calculated by combining the history with the overall distribution proportion data of different age groups of the elevator taking personnel in the current time period and the overall distribution proportion data of different age groups of the elevator taking personnel in the same time period nearest to the current time period.

Optionally, analyzing and confirming the degree of influence of the contaminants includes:

analyzing and judging whether the data of the coverage area of the pollutants exceed first preset area data or not;

if the data of the coverage area of the pollutants exceeds the first preset area data, judging that the influence degree of the pollutants is serious;

if the pollutant coverage area data is smaller than the first preset area data, analyzing whether the pollutant coverage area data exceeds second preset area data or not, wherein the first preset area data exceeds the second preset area data;

if the data of the coverage area of the pollutants is smaller than the first preset area data and exceeds the second preset area data, analyzing and calculating the effective tolerance of the elevator taking personnel at the current time period based on the distribution ratio data of the elevator taking personnel at different age groups at the current time period and the tolerance of the elevator taking personnel at different age groups to different pollutants, wherein the tolerance is embodied by a probability value from 0 to 100 percent, 0 represents that the tolerance is completely intolerable, and 100 percent represents that the tolerance is completely accepted;

if the effective tolerance of the elevator taking personnel at the current time is lower than the first preset tolerance, judging that the influence degree of the pollutants is serious;

if the effective tolerance of the elevator taking personnel at the current time exceeds a first preset tolerance, judging that the influence degree of the pollutants is general;

if the data of the coverage area of the pollutants is lower than the second preset area data, analyzing and calculating the effective tolerance of the elevator taking personnel at the current time period based on the distribution ratio data of the elevator taking personnel at different age groups at the current time period and the tolerance of the elevator taking personnel at different age groups to different pollutants;

if the effective tolerance of the elevator taking personnel at the current time is lower than a second preset tolerance, judging that the influence degree of the pollutants is serious, wherein the second preset tolerance is lower than the first preset tolerance;

if the effective tolerance of the elevator taking personnel at the current time interval exceeds a second preset tolerance and is lower than a third preset tolerance, judging that the influence degree of the pollutants is general, wherein the third preset tolerance is higher than the second preset tolerance;

and if the effective tolerance of the elevator taking personnel at the current time interval exceeds a third preset tolerance, judging that the influence degree of the pollutants is slight.

By adopting the technical scheme, the influence degree of the pollutants can be effectively analyzed and determined by comprehensively considering the data of the coverage area of the pollutants, the distribution ratio data of different age groups of elevator passengers at the current time and the tolerance of the different age groups to different pollutants.

Optionally, analyzing and calculating the effective tolerance of the elevator passenger in the current time period includes:

inquiring and acquiring the tolerance of elevator taking personnel of different ages to different pollutants from a preset first database in which the tolerance of the elevator taking personnel of different ages to different pollutants is stored, wherein the type of the pollutants at this time is taken as an inquiry object;

based on the tolerance of different age groups to the pollutants at this time and different age groups of elevator personnel taken at the current time, the effective tolerance of the elevator personnel taken at the current time is calculated by applying a calculation formula, and the specific calculation formula is as follows: z = a q1+ B q2+ C q3+ D q4+ E q5, where Z is the effective tolerance of taking elevator people in the current time period, q1 is the distribution proportion data of taking elevator people in the childhood section, and a is the tolerance of taking elevator people in the childhood section to the current pollutant; q2 is distribution proportion data of elevator taking personnel in the juvenile stage, and B is tolerance of the elevator taking personnel in the juvenile stage to the current pollutants; q3 is distribution proportion data of elevator taking personnel in the young section, and C is tolerance of the elevator taking personnel in the young section to the pollutants; q4 is distribution proportion data of elevator passengers in the middle-aged period, and D is tolerance of the elevator passengers in the middle-aged period to the pollutants; q5 is distribution proportion data of elevator taking personnel in the old age, and E is tolerance of the elevator taking personnel in the old age to the pollutants.

By adopting the technical scheme, how to obtain the tolerance of the elevator taking personnel of different age groups to the pollutant at this time is specifically introduced, and the corresponding formula is applied to combine the different age groups of the elevator taking personnel at the current time, so that the effective tolerance of the elevator taking personnel at the current time is analyzed and calculated.

Optionally, the querying and obtaining tolerance of elevator passengers of different ages to the current pollutant includes:

analyzing and obtaining whether the number of the types of the pollutants is multiple;

if the type of the pollutants is only one, the type of the pollutants at this time is taken as an inquiry object, and the tolerance of elevator taking personnel at different ages to the pollutants at this time is inquired and obtained in a first database;

if the types of the pollutants are multiple, analyzing the proportion data of each pollutant in the current pollutant, and simultaneously, taking the types of each pollutant as query objects one by one, and querying in a first database to obtain the tolerance of elevator taking personnel of different ages to the pollutants;

and calculating the product of the proportion data of each pollutant in the current pollutant and the tolerance of the elevator passengers in the same age group on the corresponding pollutant one by one, and taking the sum of all products as the tolerance of the elevator passengers in the corresponding age group on the current pollutant.

By adopting the technical scheme, the type condition of the pollutants is further considered, and different calculation modes are applied according to the different types of the pollutants, so that the effective tolerance of the elevator personnel taking at the current time is calculated more accurately.

Optionally, the analyzing and determining the person who has the shortest expected time to process the contaminant, who is adapted to the degree of influence of the current contaminant and carries the corresponding tool to the elevator car in which the contaminant is present, includes:

inquiring and acquiring the processing completion time of the corresponding pollutants and the tools required to be applied by the pollutants according to the influence degrees of the pollutants as inquiry objects from a preset second database in which the influence degrees of the pollutants, the processing completion time set by the pollutants with the corresponding influence degrees and the tools required to be applied by the pollutants with the corresponding influence degrees are stored;

searching the working state of the pollutant treating person and the real-time position of the corresponding pollutant treating person from a preset third database in which the pollutant treating person, the current working state of the corresponding pollutant treating person and the real-time position of the corresponding pollutant treating person are stored, wherein the working state of the pollutant treating person comprises a busy state, a rest state and an idle state;

comprehensively analyzing and determining the pollutant treating person with the shortest time consumption for reaching the site by carrying the corresponding tool based on the current position of the pollutant treating person, the storage position of the corresponding tool and the probability of carrying the corresponding tool by the pollutant treating person;

if the influence degree of the pollutants is serious, the time for finishing the treatment of the corresponding pollutants is used as the preset treatment time, and the staff with the shortest time consumption for reaching the site with the corresponding tool is selected from all the staff for treating the pollutants as the informed staff for treating the pollutants;

if the influence degree of the pollutants is general, selecting the staff with the shortest time consumption for reaching the site with the corresponding tool from the staff in the busy state and the idle state for treating the pollutants as the informed staff for treating the pollutants;

if the influence degree of the pollutants is general, selecting the staff with the shortest time consumption for reaching the site with the corresponding tool from the staff in the busy state and the idle state for treating the pollutants as the informed staff for treating the pollutants;

and if the influence degree of the pollutants is slight, selecting the staff with the shortest time consumption for carrying the corresponding tool to arrive at the site from the staff for treating the pollutants in the busy state and the idle state as the informed staff for treating the pollutants.

By adopting the technical scheme, the pollutant processing time and the tool required to be applied are comprehensively considered, the current position of the pollutant processing personnel, the corresponding tool storage position and the probability that the pollutant processing personnel carry the corresponding tool are comprehensively considered, the influence degree of the current pollutant can be effectively analyzed and determined, and the shortest time consumption prediction is realized when the pollutant processing personnel carry the corresponding tool to reach the elevator car with the pollutant.

Optionally, the comprehensive analysis for determining the time taken for each pollutant treating person to arrive at the site with the corresponding tool comprises:

acquiring the current position of a person handling the pollutants, the position of an elevator with the pollutants and the storage position of a corresponding tool;

inquiring and acquiring the probability that each pollutant treating person carries a corresponding tool in the current time period by taking the corresponding tool and the current time period as inquiry objects from a preset fourth database in which the probabilities that the pollutant treating persons carry different tools in different time periods are stored;

planning a shortest route which takes the position of a person who treats the pollutants as a starting point, passes through the position where the corresponding tool exists and finally reaches the position where the elevator with the pollutants exists, taking the shortest route as a dividend, taking the preset traveling speed of the person who treats the pollutants as a divisor, and analyzing and calculating the time consumption of the person who treats the pollutants for receiving the corresponding tool midway and reaching the position where the elevator with the pollutants exists;

planning a shortest route which takes the position of a person who treats the pollutants as a starting point and finally reaches the position of the elevator with the pollutants, taking the shortest route as a dividend, taking the preset traveling speed of the person who treats the pollutants as a divisor, and analyzing and calculating the consumed time of the person who treats the pollutants, who originally carries a corresponding tool and reaches the position of the elevator with the pollutants;

based on the time consumption of taking a corresponding tool midway by pollutant treating personnel and reaching the position of the elevator with pollutants, the time consumption of carrying the corresponding tool originally by the pollutant treating personnel and reaching the position of the elevator with pollutants and the probability of carrying the corresponding tool by the pollutant treating personnel at the current time, the time consumption of carrying the corresponding tool by each pollutant treating personnel to reach the site is calculated one by applying a preset formula, and the specific formula is as follows: y = t1 p1+ t2 (1-p 1), wherein Y is the time taken by the person handling the contaminant to arrive at the site with the corresponding tool, t1 is the time taken by the person handling the contaminant to arrive at the location where the contaminant elevator is present, p1 is the probability that the person handling the contaminant carries the corresponding tool at the current time, and t2 is the time taken by the person handling the contaminant to take the corresponding tool halfway and arrive at the location where the contaminant elevator is present.

By adopting the technical scheme, the time consumed when each pollutant treating person carries the corresponding tool to arrive at the site can be effectively analyzed and calculated by combining the probability that each pollutant treating person carries the corresponding tool at the current time period, the time consumed when each pollutant treating person originally carries the corresponding tool and arrives at the position where the pollutant elevator exists and the probability that each pollutant treating person carries the corresponding tool at the current time period.

In a second aspect, the application provides a system for monitoring a sanitary environment in an elevator car, which adopts the following technical scheme:

an elevator car sanitation monitoring system, comprising a memory, a processor and a program stored on the memory and operable on the processor, the program being capable of being loaded into execution by the processor to implement an elevator car sanitation monitoring method as described in the first aspect.

By adopting the technical scheme, through the calling of the related program, the pollutant treating person which is adaptive to the influence degree of the current pollutant and has the shortest estimated time consumption when the corresponding tool reaches the elevator car with the pollutant can be analyzed and determined to serve as the pollutant treating person for confirming the notification, and the notification information is sent to the terminal of the pollutant treating person for confirming the notification.

In a third aspect, the present application provides a computer storage medium, which adopts the following technical solutions:

a computer storage medium comprising a program that is capable of being loaded into execution by a processor to carry out a method of monitoring a sanitary environment in an elevator car according to the first aspect.

By adopting the technical scheme, through the calling of the related program, the pollutant treating person which is adaptive to the influence degree of the current pollutant and has the shortest estimated time consumption when the corresponding tool reaches the elevator car with the pollutant can be analyzed and determined to serve as the pollutant treating person for confirming the notification, and the notification information is sent to the terminal of the pollutant treating person for confirming the notification.

To sum up, the beneficial technical effect of this application does: the influence degree of the pollutants is comprehensively confirmed by combining the self condition of the pollutants and the tolerance of the people taking the elevator to the pollutants, and the informed people treating the pollutants are determined by combining the influence degree of the pollutants, so that the treatment efficiency of the pollutants is better guaranteed.

Drawings

Fig. 1 is a schematic diagram of the overall steps of a method for monitoring the sanitary environment in an elevator car according to an embodiment of the present application.

Fig. 2 is a schematic diagram of the step of acquiring the age group distribution proportion data of the persons who take the elevator at the current time period, which is mentioned in step S200 in fig. 1.

Fig. 3 is a schematic diagram of the steps of analyzing and confirming the influence degree of the contaminants mentioned in step S200 in fig. 1.

Fig. 4 is a schematic diagram of the steps of analyzing and calculating the effective tolerance of the elevator passenger at the current time slot in step S2D0 and step S2E0 in fig. 3.

Fig. 5 is a schematic diagram of the steps of querying and obtaining the tolerance of the elevator passengers of different age groups to the current pollutant, which is mentioned in step Sa00 in fig. 4.

Fig. 6 is a schematic diagram of the steps of analyzing the data mentioned in step S300 of fig. 1 to determine the person who has dealt with the contaminant with the shortest expected time to reach the elevator car where the contaminant is present, adapted to the degree of influence of the current contaminant.

FIG. 7 is a schematic diagram of the integrated analysis process referenced in step S3B0 of FIG. 6 to determine the time-consuming arrival of each contaminant-handling person at the site with the corresponding tool.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

Referring to fig. 1, a method for monitoring a sanitary environment in an elevator car disclosed in the present application includes steps S100 to S300.

In step S100, information on the position of the contaminant in the elevator car, information on the type of the contaminant, and information on the coverage area of the contaminant are obtained.

The information about the types of contaminants mentioned in step S100 mainly includes, but is not limited to, feces of animals, urine of people, and vomiting of drunk people; the obtaining of the information about the position of the pollutant in the elevator car and the information about the type of the pollutant mentioned in step S100 can be realized by the following steps: firstly, color information of three-dimensional pixel points at the bottom of the elevator car is collected through a depth camera arranged in the elevator car and transmitted to the terminal equipment, and the terminal equipment judges the type and the area of pollutants according to the color information of the three-dimensional pixel points at the bottom of the elevator car.

In step S200, based on the information of the location of the contaminant in the elevator, the information of the type of the contaminant, the information of the coverage area of the contaminant, the distribution proportion data of the age groups of the persons who take the elevator at the current time and the tolerance of the persons at different age groups to the contaminant, the influence degree of the contaminant is analyzed and confirmed, wherein the influence degree of the contaminant can be classified as serious, general or slight.

Referring to fig. 2, the acquisition of the age group distribution proportion data of the persons who take the elevator at the current time period mentioned in step S200 may be divided into steps S2a0 to S2b 0.

In step S2a0, acquiring distribution ratio data of different age groups of elevator passengers in different periods in history, wherein the age groups of the elevator passengers are divided as follows: the childhood period is as follows: 0 to 6 years old; juvenile stage: from 7 to 17 years old; young age period: 18 to 40 years old; and (4) middle-aged period: age 41 to 65 years old; old age: after age 66.

The acquisition of the distribution ratio data of different age groups of elevator passengers in different historical time periods mentioned in step S2a0 can be obtained by querying a database storing the distribution ratio data of different age groups of elevator passengers in different historical time periods.

In addition, the above-mentioned time period is a specific few hours, for example, 1 pm, and 13 hours.

In step S2b0, the data of the overall distribution ratio of the history to the different age groups of the elevator passengers who are present in the same time slot and the data of the overall distribution ratio of the different age groups of the elevator passengers who are present in the same time slot most adjacent to the same time slot are statistically analyzed, and the average value of the two data is used as the data of the distribution ratio of the different age groups of the elevator passengers who are present in the current time slot.

For example, when the current time is 13, in the overall distribution ratio data of different age groups of elevator passengers who take elevator in the same time period in history as 13, the ratio of elevator passengers taking in the juvenile period is 20%, the ratio of elevator passengers taking in the juvenile period is 30%, the ratio of elevator passengers taking in the youth period is 10%, the ratio of elevator passengers taking in the middle-aged period is 20%, and the ratio of elevator passengers taking in the old period is 20%.

In the data of the overall distribution ratios of different age groups among the elevator passengers nearest to 13, the ratio of the elevator passengers in the juvenile period is 30%, the ratio of the elevator passengers in the juvenile period is 10%, the ratio of the elevator passengers in the youth period is 20%, the ratio of the elevator passengers in the middle age period is 30%, and the ratio of the elevator passengers in the old period is 10%.

In the distribution ratio data of different age groups of elevator passengers taking in the current time period, the ratio of elevator passengers taking in the juvenile time period is 25%, the ratio of elevator passengers taking in the juvenile time period is 20%, the ratio of elevator passengers taking in the youth time period is 15%, the ratio of elevator passengers taking in the middle age time period is 20%, and the ratio of elevator passengers taking in the old time period is 15%.

Referring to fig. 3, the analysis of step S200 for confirming the influence of the contaminants can be divided into steps S2a0 through S2D 0.

In step S2a0, the analysis determines whether the pollutant coverage area data exceeds a first preset area data. If the data of the pollutant coverage area exceeds the first preset area data, step S2B0 is executed. If the data of the pollutant coverage area is smaller than the first preset area data, step S2C0 is executed.

The first preset area data mentioned in step S2a0 may be 2 square meters, or may be other areas defined by the user.

In step S2B0, the degree of influence of the contaminants is judged to be serious.

In step S2C0, it is analyzed whether the pollutant coverage area data exceeds a second preset area data, wherein the first preset area data exceeds the second preset area data. If the pollutant coverage area data is smaller than the first preset area data and exceeds the second preset area data, step S2D0 is executed. If the data of the pollutant coverage area is lower than the second predetermined area data, step S2E0 is executed.

The second preset area data mentioned in step S2C0 may be 1 square meter, or may be other areas defined by the user.

In step S2D0, based on the distribution ratio data of the people who take the elevator in the current time period in different age groups and the tolerance of the people in different age groups to different pollutants, the effective tolerance of the people who take the elevator in the current time period is analyzed and calculated, wherein the tolerance is represented by a probability value from 0 to 100%, 0 represents completely intolerable, and 100% represents completely accepted.

For example, the tolerance of the elevator passengers in the old age group to vomit is 50%, the tolerance to dog urine is 40%, and the specific tolerance can be obtained by querying a database storing the tolerances for different pollutants obtained by investigation in different age groups.

And if the effective tolerance of the elevator taking personnel at the current time is lower than the first preset tolerance, judging that the influence degree of the pollutants is serious.

For example, the first preset tolerance may be 50%, or may be defined by the user based on personal needs.

If the effective tolerance of the elevator taking personnel at the current time interval exceeds the first preset tolerance, the influence degree of the pollutants is judged to be general.

In step S2E0, based on the distribution ratio data of the persons who take the elevator in the current time period in different age groups and the tolerance of the persons in different age groups to different pollutants, the effective tolerance of the persons who take the elevator in the current time period is analyzed and calculated.

And if the effective tolerance of the elevator taking personnel at the current time interval is lower than a second preset tolerance, judging that the influence degree of the pollutants is serious, wherein the second preset tolerance is lower than the first preset tolerance.

For example, the second preset tolerance may be 40%, or may be defined by the user based on personal needs, but needs to be lower than the first preset tolerance.

If the effective tolerance of the elevator taking personnel at the current time interval exceeds the second preset tolerance and is lower than a third preset tolerance, the influence degree of the pollutants is judged to be general, wherein the third preset tolerance is higher than the second preset tolerance.

For example, the third preset tolerance here may be 44%, or may be defined by the user based on personal needs, and when the effective tolerance of the elevator passenger is 42 degrees, it is determined that the influence degree of the pollutant is general.

And if the effective tolerance of the elevator taking personnel at the current time interval exceeds a third preset tolerance, judging that the influence degree of the pollutants is slight.

Referring to fig. 4, the analysis mentioned in step S2D0 and step S2E0 can be divided into steps Sa00 to Sb00 to calculate the effective tolerance of the elevator passengers in the current time slot.

In step Sa00, tolerance of elevator passengers of different ages to different pollutants is queried and obtained from a preset first database in which tolerance of elevator passengers of different ages to different pollutants is stored, with the type of the current pollutant as a query object.

Referring to fig. 5, the query mentioned in step Sa00 to obtain the tolerance of the present contaminant for elevator passengers of different ages can be divided into steps Saa0 to Sad 0.

In step Saa0, it is analyzed whether the number of the types of the acquired contaminants is plural. If the number of the types of the contaminants is 1, the step Sab0 is performed. If the number of the types of the contaminants is plural, the step Sac0 is performed.

In step Sab0, the current type of the contaminant is used as the query object, and the tolerance of the elevator riding personnel of different ages to the current contaminant is queried and obtained in the first database.

In step Sac0, the proportion data of each pollutant in the current pollutant is analyzed, and meanwhile, the tolerance of elevator passengers of different ages to the pollutants is inquired and obtained in a first database by taking the type of each pollutant as an inquiry object one by one.

In step Sad0, the product of the proportion data of each pollutant in the current pollutant and the tolerance of the elevator passengers in the same age group about the corresponding pollutant is calculated one by one, and the sum of all the products is used as the tolerance of the elevator passengers in the corresponding age group to the current pollutant.

For example, if 2 kinds of pollutants are assumed, namely a pollutant a and a pollutant b, wherein the proportion of the pollutant a is 30%, the proportion of the pollutant b is 70%, the tolerance of the elevator passenger in the juvenile period to the pollutant a is 20%, and the tolerance of the elevator passenger in the juvenile period to the pollutant b is 30%, then the tolerance of the elevator passenger in the juvenile period to the current pollutant is 27%.

In step Sb00, based on the tolerance of different age groups to the current pollutant and the different age groups of the elevator people taking the elevator at the current time, the effective tolerance of the elevator people taking the elevator at the current time is calculated by applying a calculation formula, and the specific calculation formula is as follows: z = a q1+ B q2+ C q3+ D q4+ E q5, where Z is the effective tolerance of taking elevator people in the current time period, q1 is the distribution proportion data of taking elevator people in the childhood section, and a is the tolerance of taking elevator people in the childhood section to the current pollutant; q2 is distribution proportion data of elevator taking personnel in the juvenile stage, and B is tolerance of the elevator taking personnel in the juvenile stage to the current pollutants; q3 is distribution proportion data of elevator taking personnel in the young section, and C is tolerance of the elevator taking personnel in the young section to the pollutants; q4 is distribution proportion data of elevator passengers in the middle-aged period, and D is tolerance of the elevator passengers in the middle-aged period to the pollutants; q5 is distribution proportion data of elevator taking personnel in the old age, and E is tolerance of the elevator taking personnel in the old age to the pollutants.

For example, in the distribution proportion data of different age groups of elevator passengers at the current time, the proportion of elevator passengers at the juvenile time is 25%, the proportion of elevator passengers at the juvenile time is 20%, the proportion of elevator passengers at the youth time is 15%, the proportion of elevator passengers at the middle age time is 20%, and the proportion of elevator passengers at the old time is 15%; the tolerance of elevator people in the juvenile period to the pollutants at this time is 30%, the ratio of elevator people in the juvenile period to the pollutants at this time is 40%, the tolerance of elevator people in the young period to the pollutants at this time is 10%, the tolerance of elevator people in the middle-aged period to the pollutants at this time is 10%, and the tolerance of elevator people in the old period to the pollutants at this time is 30%.

According to the formula of Z = A × q1+ B × q2+ C × q3+ D × q4+ E × q5, the effective tolerance of the elevator passenger in the current time period can be calculated to be 23.5%.

In step S300, based on the degree of influence of the pollutant, the time for completing the treatment set for the pollutant with the corresponding degree of influence, the tool and the position to which the pollutant with the corresponding degree of influence needs to be applied, and the working state of the person handling the pollutant, the current position, and the probability of carrying the corresponding tool with him, the person handling the pollutant with the shortest expected time consumption, which is adapted to the degree of influence of the current pollutant and carries the corresponding tool to reach the elevator car with the pollutant, is analyzed and determined as the person handling the pollutant for confirmation notification, and notification information is sent to the terminal of the person handling the pollutant for confirmation notification.

Referring to fig. 6, wherein the analysis mentioned in step S300 determines the person who has the shortest expected time to process contaminants, who is adapted to the degree of influence of the current contaminants and carries the corresponding tool to the elevator car where contaminants are present, may be divided into steps S3a0 to S3E 0.

In step S3a0, from a preset second database storing the influence degrees of the pollutants, the processing completion time set for the pollutants of the corresponding influence degrees, and the tool to be applied to the pollutants of the corresponding influence degrees, the influence degrees of the pollutants are used as query objects, and the tool to be applied and the processing completion time of the corresponding pollutants are queried and obtained.

And searching the working state of the pollutant treating personnel and the real-time position of the corresponding pollutant treating personnel from a preset third database in which the pollutant treating personnel, the current working state of the corresponding pollutant treating personnel and the real-time position of the corresponding pollutant treating personnel are stored, wherein the working states of the pollutant treating personnel comprise a busy state, a rest state and an idle state.

For example, the processing completion time of the pollutant A is 30 minutes, the required tool is a mop, and the real-time position of the corresponding pollutant treating person can be obtained by installing a position tracker on a terminal held by the pollutant treating person.

In step S3B0, based on the current location of the person handling the contaminant, the storage location of the corresponding tool, and the probability that the person handling the contaminant carries the corresponding tool with him, the person handling the contaminant who takes the shortest time to arrive at the site with the corresponding tool is determined by comprehensive analysis.

Referring to fig. 7, wherein the integrated analysis referred to in step S3B0 determines the time taken for each contaminant handling person to arrive at the site with the corresponding tool includes steps S3Ba through S3 Bd.

In step S3Ba, the current location of the person handling the contaminant, the location of the elevator where the contaminant is present, and the corresponding tool storage location are obtained.

The corresponding tool storage location may be obtained by querying a preset database storing tool storage locations.

In step S3Bb, from a preset fourth database storing probabilities that people who process pollutants carry different tools in different time periods, the probability that each person who process pollutants carries a corresponding tool in the current time period is obtained by querying, with the corresponding tool and the current time period as query objects.

In step S3Bc, a shortest route that takes the location of the person handling the pollutants as a starting point, passes through the location of the corresponding tool and finally reaches the location of the elevator with the pollutants is planned, the shortest route is used as a dividend, the preset traveling speed of the person handling the pollutants is used as a divisor, and the time consumed for the person handling the pollutants to retrieve the corresponding tool midway and reach the location of the elevator with the pollutants is analyzed and calculated.

And planning the shortest route which takes the position of the pollutant treating person as a starting point and finally reaches the position of the elevator with the pollutants, taking the shortest route as a dividend, taking the preset traveling speed of the pollutant treating person as a divisor, and analyzing and calculating the consumed time of the pollutant treating person which originally carries a corresponding tool and reaches the position of the elevator with the pollutants.

Wherein, the shortest route which is mentioned in step S3Bc and takes the position of the person handling the contaminant as the starting point, passes through the position where the corresponding tool exists, and finally reaches the position where the contaminant exists is realized according to the following steps: firstly, planning all routes; next, the route with the shortest distance is selected from all the routes.

For example, assuming a distance of 3 km and a travel speed of 30 km/h for the person handling the contaminant, the time taken to handle the contaminant is 6 minutes.

In step S3Bd, based on the time consumed by the pollutant treating person to retrieve the corresponding tool midway and arrive at the location where the pollutant exists, the time consumed by the pollutant treating person to carry the corresponding tool originally and arrive at the location where the pollutant exists, and the probability that the pollutant treating person carries the corresponding tool at the current time, a preset formula is applied to calculate the time consumed by each pollutant treating person to carry the corresponding tool to arrive at the site one by one, and the specific formula is as follows: y = t1 p1+ t2 (1-p 1), wherein Y is the time taken by the person handling the contaminant to arrive at the site with the corresponding tool, t1 is the time taken by the person handling the contaminant to arrive at the location where the contaminant elevator is present, p1 is the probability that the person handling the contaminant carries the corresponding tool at the current time, and t2 is the time taken by the person handling the contaminant to take the corresponding tool halfway and arrive at the location where the contaminant elevator is present.

For example, assuming that it takes 10 minutes for a person handling a contaminant to arrive at a location where a contaminant elevator exists, with a probability of 30%, and it takes 20 minutes for the person handling the contaminant to take the corresponding tool halfway and arrive at the location where the contaminant elevator exists, Y can be analytically calculated as 17 minutes according to Y = t1 p1+ t2 (1-p 1).

In step S3C0, if the influence of the pollutant is serious, the time for completing the treatment of the corresponding pollutant is used as the preset treatment time, and the worker with the shortest time to arrive at the site with the corresponding tool is selected as the notified pollutant treating worker.

In step S3D0, if the influence degree of the pollutant is general, the worker who takes the shortest time to arrive at the site with the corresponding tool is selected as the notified pollutant treating person from the pollutant treating persons in the busy state and the idle state.

In step S3E0, if the degree of influence of the contamination is slight, the worker who takes the shortest time to arrive at the site with the corresponding tool is selected as the notified person who handles the contamination from the persons who handle the contamination in the busy state and the free state.

The implementation principle of the embodiment is as follows:

the method comprises the steps of firstly analyzing and judging the position of a pollutant in an elevator, the type of the pollutant and the coverage area of the pollutant, then comprehensively analyzing and confirming the influence degree of the pollutant by combining the distribution proportion data of the age groups of people taking the elevator at the current time and the tolerance of people of different age groups to the pollutant, and comprehensively determining the informed pollutant treating person by considering the condition of the pollutant treating person after confirming the influence degree of the pollutant.

An embodiment of the present invention provides a computer-readable storage medium, which includes a program capable of being loaded and executed by a processor to implement any one of the methods shown in fig. 1-7.

The computer-readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

Based on the same inventive concept, the embodiment of the invention provides an elevator car interior sanitary environment monitoring system, which comprises a memory and a processor, wherein the memory is stored with a program capable of running on the processor to realize the method shown in any one of the figures 1 to 7.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (7)

1. A method for monitoring a sanitary environment in an elevator car, comprising:

acquiring position information, pollutant type information and pollutant coverage area information of pollutants in an elevator car;

analyzing and confirming the influence degree of the pollutants based on the position information, the pollutant type information and the pollutant coverage area information of the pollutants in the elevator, the distribution proportion data of the age groups of the people taking the elevator at the current time and the tolerance of the people of different age groups to the pollutants, wherein the influence degree of the pollutants can be classified into serious, general and slight;

analyzing and determining the pollutant treating person which is adaptive to the influence degree of the current pollutant and has the shortest time consumption for reaching the elevator car with the corresponding tool to serve as the pollutant treating person for confirming the notification, and sending notification information to a terminal held by the pollutant treating person for confirming the notification, based on the influence degree of the pollutant, the set treatment finishing time of the pollutant with the corresponding influence degree, the tool and the position of the pollutant required to be applied with the corresponding influence degree, the working state of the pollutant treating person, the current position and the probability of carrying the corresponding tool with the pollutant treating person;

the acquisition of the age group distribution proportion data of the elevator passengers at the current time comprises the following steps:

acquiring distribution proportion data of different age groups of elevator passengers in different historical time periods, wherein the age groups of the elevator passengers are divided as follows: the childhood period is as follows: 0 to 6 years old; juvenile stage: from 7 to 17 years old; young age period: 18 to 40 years old; and (4) middle-aged period: age 41 to 65 years old; old age: after age 66 years;

carrying out statistical analysis to obtain history and integral distribution proportion data of different age groups in elevator taking personnel who belong to the same time interval at present, and integral distribution proportion data of different age groups in elevator taking personnel who belong to the same time interval at the nearest time, and taking the average value of the history and the integral distribution proportion data as the distribution proportion data of different age groups in elevator taking personnel at the present time interval;

analyzing and confirming the influence degree of the pollutants comprises:

analyzing and judging whether the data of the coverage area of the pollutants exceed first preset area data or not;

if the data of the coverage area of the pollutants exceeds the first preset area data, judging that the influence degree of the pollutants is serious;

if the pollutant coverage area data is smaller than the first preset area data, analyzing whether the pollutant coverage area data exceeds second preset area data or not, wherein the first preset area data exceeds the second preset area data;

if the data of the coverage area of the pollutants is smaller than the first preset area data and exceeds the second preset area data, analyzing and calculating the effective tolerance of the elevator taking personnel at the current time period based on the distribution ratio data of the elevator taking personnel at different age groups at the current time period and the tolerance of the elevator taking personnel at different age groups to different pollutants, wherein the tolerance is embodied by a probability value from 0 to 100 percent, 0 represents that the tolerance is completely intolerable, and 100 percent represents that the tolerance is completely accepted;

if the effective tolerance of the elevator taking personnel at the current time is lower than the first preset tolerance, judging that the influence degree of the pollutants is serious;

if the effective tolerance of the elevator taking personnel at the current time exceeds a first preset tolerance, judging that the influence degree of the pollutants is general;

if the data of the coverage area of the pollutants is lower than the second preset area data, analyzing and calculating the effective tolerance of the elevator taking personnel at the current time period based on the distribution ratio data of the elevator taking personnel at different age groups at the current time period and the tolerance of the elevator taking personnel at different age groups to different pollutants;

if the effective tolerance of the elevator taking personnel at the current time is lower than a second preset tolerance, judging that the influence degree of the pollutants is serious, wherein the second preset tolerance is lower than the first preset tolerance;

if the effective tolerance of the elevator taking personnel at the current time interval exceeds a second preset tolerance and is lower than a third preset tolerance, judging that the influence degree of the pollutants is general, wherein the third preset tolerance is higher than the second preset tolerance;

and if the effective tolerance of the elevator taking personnel at the current time interval exceeds a third preset tolerance, judging that the influence degree of the pollutants is slight.

2. The method of claim 1, wherein the method comprises the steps of: the analysis and calculation of the effective tolerance of the elevator passengers in the current time period comprises the following steps:

inquiring and acquiring the tolerance of elevator taking personnel of different ages to different pollutants from a preset first database in which the tolerance of the elevator taking personnel of different ages to different pollutants is stored, wherein the type of the pollutants at this time is taken as an inquiry object;

based on the tolerance of different age groups to the pollutants at this time and different age groups of elevator personnel taken at the current time, the effective tolerance of the elevator personnel taken at the current time is calculated by applying a calculation formula, and the specific calculation formula is as follows: z = a q1+ B q2+ C q3+ D q4+ E q5, where Z is the effective tolerance of taking elevator people in the current time period, q1 is the distribution proportion data of taking elevator people in the childhood section, and a is the tolerance of taking elevator people in the childhood section to the current pollutant; q2 is distribution proportion data of elevator taking personnel in the juvenile stage, and B is tolerance of the elevator taking personnel in the juvenile stage to the current pollutants; q3 is distribution proportion data of elevator taking personnel in the young section, and C is tolerance of the elevator taking personnel in the young section to the pollutants; q4 is distribution proportion data of elevator passengers in the middle-aged period, and D is tolerance of the elevator passengers in the middle-aged period to the pollutants; q5 is distribution proportion data of elevator taking personnel in the old age, and E is tolerance of the elevator taking personnel in the old age to the pollutants.

3. The method of claim 2, wherein the method comprises the steps of: the tolerance of the elevator taking personnel at different ages to the pollutants is inquired and obtained by the following steps:

analyzing and obtaining whether the number of the types of the pollutants is multiple;

if the type of the pollutants is only one, the type of the pollutants at this time is taken as an inquiry object, and the tolerance of elevator taking personnel at different ages to the pollutants at this time is inquired and obtained in a first database;

if the types of the pollutants are multiple, analyzing the proportion data of each pollutant in the current pollutant, and simultaneously, taking the types of each pollutant as query objects one by one, and querying in a first database to obtain the tolerance of elevator taking personnel of different ages to the pollutants;

and calculating the product of the proportion data of each pollutant in the current pollutant and the tolerance of the elevator passengers in the same age group on the corresponding pollutant one by one, and taking the sum of all products as the tolerance of the elevator passengers in the corresponding age group on the current pollutant.

4. A method of monitoring the sanitary environment in an elevator car according to any of claims 1 to 3, characterized in that: the analysis determines the person who takes the shortest expected time to treat the contaminant, who is adapted to the degree of influence of the current contaminant and carries the corresponding tool to the elevator car in which the contaminant is present, including:

inquiring and acquiring the processing completion time of the corresponding pollutants and the tools required to be applied by the pollutants according to the influence degrees of the pollutants as inquiry objects from a preset second database in which the influence degrees of the pollutants, the processing completion time set by the pollutants with the corresponding influence degrees and the tools required to be applied by the pollutants with the corresponding influence degrees are stored;

searching the working state of the pollutant treating person and the real-time position of the corresponding pollutant treating person from a preset third database in which the pollutant treating person, the current working state of the corresponding pollutant treating person and the real-time position of the corresponding pollutant treating person are stored, wherein the working state of the pollutant treating person comprises a busy state, a rest state and an idle state;

comprehensively analyzing and determining the pollutant treating person with the shortest time consumption for reaching the site by carrying the corresponding tool based on the current position of the pollutant treating person, the storage position of the corresponding tool and the probability of carrying the corresponding tool by the pollutant treating person;

if the influence degree of the pollutants is serious, the time for finishing the treatment of the corresponding pollutants is used as the preset treatment time, and the staff with the shortest time consumption for reaching the site with the corresponding tool is selected from all the staff for treating the pollutants as the informed staff for treating the pollutants;

if the influence degree of the pollutants is general, selecting the staff with the shortest time consumption for reaching the site with the corresponding tool from the staff in the busy state and the idle state for treating the pollutants as the informed staff for treating the pollutants;

and if the influence degree of the pollutants is slight, selecting the staff with the shortest time consumption for carrying the corresponding tool to arrive at the site from the staff for treating the pollutants in the busy state and the idle state as the informed staff for treating the pollutants.

5. The method of claim 4, wherein the method comprises the steps of: the comprehensive analysis for determining the time consumption of each pollutant treating person to arrive at the site with the corresponding tool comprises the following steps:

acquiring the current position of a person handling the pollutants, the position of an elevator with the pollutants and the storage position of a corresponding tool;

inquiring and acquiring the probability that each pollutant treating person carries a corresponding tool in the current time period by taking the corresponding tool and the current time period as inquiry objects from a preset fourth database in which the probabilities that the pollutant treating persons carry different tools in different time periods are stored;

planning a shortest route which takes the position of a person who treats the pollutants as a starting point, passes through the position where the corresponding tool exists and finally reaches the position where the elevator with the pollutants exists, taking the shortest route as a dividend, taking the preset traveling speed of the person who treats the pollutants as a divisor, and analyzing and calculating the time consumption of the person who treats the pollutants for receiving the corresponding tool midway and reaching the position where the elevator with the pollutants exists;

planning a shortest route which takes the position of a person who treats the pollutants as a starting point and finally reaches the position of the elevator with the pollutants, taking the shortest route as a dividend, taking the preset traveling speed of the person who treats the pollutants as a divisor, and analyzing and calculating the consumed time of the person who treats the pollutants, who originally carries a corresponding tool and reaches the position of the elevator with the pollutants;

based on the time consumption of taking a corresponding tool midway by pollutant treating personnel and reaching the position of the elevator with pollutants, the time consumption of carrying the corresponding tool originally by the pollutant treating personnel and reaching the position of the elevator with pollutants and the probability of carrying the corresponding tool by the pollutant treating personnel at the current time, the time consumption of carrying the corresponding tool by each pollutant treating personnel to reach the site is calculated one by applying a preset formula, and the specific formula is as follows: y = t1 p1+ t2 (1-p 1), wherein Y is the time taken by the person handling the contaminant to arrive at the site with the corresponding tool, t1 is the time taken by the person handling the contaminant to arrive at the location where the contaminant elevator is present, p1 is the probability that the person handling the contaminant carries the corresponding tool at the current time, and t2 is the time taken by the person handling the contaminant to take the corresponding tool halfway and arrive at the location where the contaminant elevator is present.

6. An elevator car sanitation monitoring system comprising a memory, a processor and a program stored on the memory and executable on the processor, the program being capable of being loaded and executed by the processor to implement an elevator car sanitation monitoring method as claimed in any one of claims 1 to 5.

7. A computer storage medium, characterized in that it comprises a program which can be loaded by a processor for carrying out a method of monitoring the hygiene environment in an elevator car according to any one of claims 1 to 5 when executed.

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