CN112053112A - Barreled water distribution method, system and storage medium - Google Patents

Abstract

The application relates to a barreled water distribution method, a barreled water distribution system and a storage medium, which solve the defect that a client cannot use the barreled water in time, and comprise the following steps: predicting the time and the quantity of barreled water required by a delivery address user next time, analyzing and calculating a proper sending opportunity, sending prediction information of the time and the quantity of the barreled water required by the user next time to a mobile phone of the delivery address user for confirmation, wherein the historical barreled water delivery condition of the delivery address user comprises the historical barreled water delivery quantity of the delivery address user, the delivery time of corresponding delivery quantity and the delivery completion time; and acquiring the information sent by the distribution address user for analysis, confirming the time and the quantity of barreled water required by the distribution address user next time based on the analyzed information, and making distribution arrangement. The method and the device have the effects of acquiring the actual distribution requirements of the distribution address users and making corresponding barreled water distribution arrangement.

Description

Barreled water distribution method, system and storage medium

Technical Field

The application relates to the technical field of barreled water distribution, in particular to a barreled water distribution method, a barreled water distribution system and a storage medium.

Background

The barreled water is purified water or mineral water which is obtained by adopting tap water or extracting underground water and treating the tap water or the extracted underground water by modern industrial technologies (reverse osmosis, electrodialysis, distillation, resin softening and the like) and is filled into a PC barrel by a filling production line.

Barreled purified water or mineral water is usually used in combination with a water dispenser, a water bucket is inverted on the water dispenser, and water in the bucket enters the water dispenser from a water inlet of the water dispenser. The user can call the water company to order the water, and the water company arranges that the staff sends the full bucket to the user.

When the barreled drinking water is used, users can or often encounter the embarrassment that the water is not delivered in time. On one hand, for a user, the user often calls the water when the barreled water is used up or is about to be used up, and at the moment, a water delivery company is often delayed due to some special conditions, so that the water delivery is not timely.

In view of the above-mentioned related art, the inventors consider that there is a drawback that affects customers to use barreled water in time.

Disclosure of Invention

In order to overcome the defect that customers can use barreled water timely, the application provides a barreled water distribution method, a barreled water distribution system and a storage medium.

In a first aspect, the application provides a barreled water distribution method, which adopts the following technical scheme:

a barreled water dispensing method, comprising:

acquiring a delivery address of the barreled water and a mobile phone number of a delivery address user;

analyzing and calculating a barreled water storage address closest to a corresponding delivery address to be taken as a barreled water delivery starting place based on historical barreled water delivery conditions of a delivery address user, predicting time and quantity of barreled water required by the delivery address user next time, analyzing and calculating a proper sending opportunity, sending prediction information of the time and quantity of barreled water required by the user next time to a mobile phone of the delivery address user for confirmation, wherein the historical barreled water delivery conditions of the delivery address user comprise historical barreled water delivery quantity of the delivery address user, delivery time of corresponding delivery quantity and delivery time of completing delivery;

and acquiring the information sent by the distribution address user for analysis, confirming the time and the quantity of barreled water required by the distribution address user next time based on the analyzed information, and making distribution arrangement.

By adopting the technical scheme, the next delivery time and delivery amount of the barreled water can be effectively analyzed and predicted based on the historical delivery condition of the barreled water delivery address, the predicted condition is notified to the delivery address user by searching the effective notification time, the actual delivery requirement of the delivery address user is better acquired through interaction with the delivery address user, and corresponding delivery arrangement is carried out.

Optionally, the analyzing and calculating step of the storage address of the barreled water closest to the corresponding delivery address is as follows: and planning a path from each barreled water storage position to the barreled water distribution address and acquiring a corresponding path by taking the barreled water distribution address as a starting point and taking the preset barreled water storage positions as end points one by one, and selecting the barreled water storage position corresponding to the shortest path as a barreled water distribution starting place of the corresponding distribution address.

By adopting the technical scheme, the barreled water delivery address closest to the current barreled water delivery address can be analyzed and calculated by comparing the distance from the preset barreled water storage position to the barreled water delivery address.

Optionally, the step of predicting the next required delivery volume of the barreled water for the user comprises the following steps:

planning a path from each barreled water storage position to the barreled water distribution address by taking the barreled water distribution address as a starting point and taking the preset barreled water storage positions as end points one by one, acquiring corresponding paths, and selecting the barreled water storage position corresponding to the shortest path as a barreled water distribution starting place of the corresponding distribution address;

searching out the historical barreled water delivery waybill number of the delivery address user, the delivery amount of the barreled water of the corresponding waybill number, the delivery time of the barreled water of the corresponding waybill number and the delivery finishing time from a first database in which the historical barreled water delivery waybill number of the user, the delivery amount of the barreled water of the corresponding waybill number and the delivery finishing time of the corresponding waybill number are stored;

the barreled water amount that the delivery address user was close to the delivery of cubic waybill number is obtained and the average value is taken as the next required barreled water delivery volume of user, if there is the decimal in the average value then gets rid of the decimal and adds 1 as the prediction delivery volume of next barreled water.

By adopting the technical scheme, on one hand, the distribution address of the barreled water closest to the distribution address is analyzed and calculated to be used as distribution arrangement, and on the other hand, the next barreled water distribution amount can be predicted based on the barreled water amount of the distribution address user approaching three times.

Optionally, the step of predicting the next time of delivering the required barreled water by the user is as follows:

searching for the consumption days corresponding to the temperature consistent with the current temperature by taking the current temperature as an inquiry object from a preset second database in which the barreled water waybill number, the average temperature of the barreled water in the period from the completion of the distribution to the completion of the drinking of the corresponding waybill number and the consumption days are stored;

acquiring the sum of the delivery amount of the order number with the temperature consistent with the current temperature from a first database as a dividend, and acquiring the daily average consumption of the current order number by taking the sum of the consumption days of the order number with the temperature consistent with the current temperature as a divisor;

with No. bottled water delivery volume of current waybill as dividend, No. bottled water's daily average consumption of current waybill is as the divisor, calculates this No. bottled water of waybill's drink total consuming time.

By adopting the technical scheme, the condition of the external environment temperature is effectively considered, and the total drinking time of the barreled water of the waybill number can be analyzed based on the previous time consumption calculation of the barreled water drinking at the same temperature as the current time.

Optionally, the analyzing and calculating step of the suitable time for sending the confirmation information to the mobile phone of the distribution address user is as follows:

analyzing and calculating the actual total delivery time of the barreled water of the corresponding waybill number based on the obtained delivery time of the waybill number of the user historical delivery frequency and the delivery completion time;

calculating the predicted delivery time consumption of the corresponding waybill number by taking the driving speed of the week number where the waybill number is located on the current day, the delivery distance of the corresponding waybill number as a dividend and the driving speed of the week number where the current day is located as a divisor from a preset third database in which the driving speed of each week is stored, wherein the delivery distance of the corresponding waybill number is the distance from the barreled water delivery starting place to the barreled water delivery address;

based on the estimated distribution time consumption and the actual distribution time consumption of the waybill number, calculating a distribution time difference by taking the actual distribution time consumption as a subtracted number and the estimated distribution time consumption as a subtracted number;

taking the average value of the distribution time difference of the unit numbers close to the third time as the predicted distribution time difference of the next unit number;

taking the distribution distance of the next order number as a dividend, taking the traveling speed of the week of the current day as a divisor, calculating the predicted distribution time consumption of the next order number, and adding the predicted distribution time difference of the previous and next order numbers to be used as the predicted distribution time consumption of the next order number;

the actual required time of the user needing the barreled water is analyzed according to the total drinking time of the barreled water of the current waybill number, the first preset time before the actual required time of the user needing the barreled water is used as the proper time for sending confirmation information to the mobile phone of the delivery address user, and the first preset time is the predicted delivery time of the next waybill number.

By adopting the technical scheme, the time difference between theoretical and actual delivery is fully considered, the time consumption for completing next delivery number is better predicted by combining the time difference condition of historical delivery and the time consumption of the current delivery theory, and the time consumption condition of the barreled water is combined, so that the proper time for sending the confirmation information to the mobile phone of the delivery address user is better analyzed.

Optionally, the method further includes the step of running synchronously with the step of sending the confirmation information to the mobile phone of the delivery address user: and starting the voice prompt device to remind the user of the distribution address of voice dialing.

By adopting the technical scheme, the addition of the voice dialing mode can more effectively ensure that the distribution address user receives the information in time and confirms and feeds back the information in time compared with the single short message notification in the prior art.

Optionally, the steps of sending back information acquisition and parsing by the delivery address user are as follows:

acquiring information sent back by a distribution address user;

taking the sum of the time period when the distribution address user receives the information and the date of the day as a first cipher group, taking a preset two-digit digital cipher as a second cipher group, and if the first cipher group is a prime number, the second cipher group is positioned before the first cipher group, and if the first cipher group is a non-prime number, the second cipher group is positioned behind the first cipher group;

taking the delivery quantity of the barreled water required by the delivery address user as first encrypted information, taking the delivery time of the barreled water required by the delivery address user as second encrypted information, wherein the first encrypted information is positioned between the first password group and the second password group, and the second encrypted information is positioned at the last position;

and comparing the data and the positions of the first password group and the second password group of the information sent back by the delivery address user with the data and the positions of the correct first password group and the correct second password group, if the comparison is consistent, extracting the first encrypted information as the delivery quantity of the barreled water required by the delivery address user, and extracting the second encrypted information as the delivery time of the barreled water required by the delivery address user.

By adopting the technical scheme, on one hand, the system can conveniently and timely acquire the delivery demands of the delivery address users by decrypting the information sent back by the delivery address users, and the problem of barreled water delivery caused by the fact that other people transmit the real demands of non-users by using the mobile phones of the delivery address users is avoided.

In a second aspect, the present application provides a bottled water delivery system, which adopts the following technical scheme:

a bottled water dispensing 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 perform the bottled water dispensing method as claimed in any one of the preceding claims.

By adopting the technical scheme, the next delivery time and delivery amount of the barreled water can be effectively analyzed and predicted based on the historical delivery condition of the barreled water delivery address, the predicted condition is notified to the delivery address user by searching the effective notification time, the actual delivery requirement of the delivery address user is better acquired through interaction with the delivery address user, and corresponding delivery arrangement is carried out.

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 loadable by a processor and that when executed performs the method of dispensing bottled water as claimed in any one of the preceding claims.

By adopting the technical scheme, through program calling, the next delivery time and delivery amount of the barreled water can be effectively analyzed and predicted based on the historical delivery condition of the barreled water delivery address, the effective notification time is searched to notify the delivery address users of the predicted condition, and the actual delivery requirements of the delivery address users can be better acquired through interaction with the delivery address users, and corresponding delivery arrangement is carried out.

To sum up, the beneficial technical effect of this application does:

1. the next delivery opportunity and delivery amount of the barreled water are effectively analyzed and predicted and interacted with the user in time, so that the delivery amount and delivery opportunity of the barreled water meet the requirements of the delivery address user;

2. the authenticity of the information sent back by the user is further ensured by encrypting and decrypting the information sent back by the user to the system, and the possibility that the information is sent by outsiders is avoided.

Drawings

Fig. 1 is a schematic view illustrating overall steps of a method for dispensing bottled water according to an embodiment of the present disclosure.

Fig. 2 is a schematic diagram of the step S200 in fig. 1 for predicting the next required delivery amount of the barreled water for the user.

Fig. 3 is a schematic diagram of the confirmation step mentioned in step S200 in fig. 1 for predicting the time for next required delivery of the bottled water by the user.

Fig. 4 is a step of analyzing and calculating the timing of sending the confirmation message to the mobile phone of the delivery address user as mentioned in step S200 of fig. 1.

Fig. 5 is a schematic diagram of the steps of the delivery address user sending back information acquisition and analysis mentioned in step S300 of fig. 1.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses a barreled water distribution method, which refers to fig. 1 and includes steps S100 to S300.

In step S100, a delivery address of the barreled water and a mobile phone number of a user of the delivery address are obtained.

The delivery address user mentioned in step S100 is a person in charge of the delivery address, and the manner of obtaining the delivery address of the bottled water and the mobile phone number of the delivery address user in step S100 may be to call a database storing related information.

In step S200, based on the historical barreled water delivery condition of the delivery address user, analyzing and calculating a storage address of the barreled water closest to the delivery corresponding delivery address as a starting point of the barreled water delivery, predicting time and quantity of the barreled water required by the delivery address user next time, analyzing and calculating a suitable sending opportunity, and sending prediction information of the time and quantity of the barreled water required by the user next time to a mobile phone of the delivery address user for confirmation, wherein the historical barreled water delivery condition of the delivery address user includes historical barreled water delivery quantity of the delivery address user, delivery time of the corresponding delivery quantity, and delivery completion time.

The analyzing and calculating step of using the storage address of the barreled water closest to the corresponding delivery address for delivering in the step S200 as the delivery starting point of the barreled water comprises the following steps: and planning a path from each barreled water storage position to the barreled water distribution address and acquiring a corresponding path by taking the barreled water distribution address as a starting point and taking the preset barreled water storage positions as end points one by one, and selecting the barreled water storage position corresponding to the shortest path as a barreled water distribution starting place of the corresponding distribution address.

The step S200 of predicting the next required delivery amount of the barreled water by the user can be divided into steps S2a0 and S2b0, referring to fig. 2.

In step S2a0, the historical barreled water delivery waybill number of the delivery address user, the delivery volume of the barreled water corresponding to the waybill number, the delivery time of the barreled water corresponding to the waybill number, and the delivery completion time are searched from the first database storing the user' S historical barreled water delivery waybill number, the delivery volume of the barreled water corresponding to the waybill number, and the delivery time and delivery completion time of the corresponding waybill number.

In step S2b0, the barreled water amount delivered by the delivery address user near the third waybill number is obtained, and the average value is taken as the next barreled water delivery amount required by the user, and if the average value has a decimal, the decimal is removed and 1 is added to be used as the predicted delivery amount of the next barreled water.

For example, if the delivery address user delivers 3 buckets, 2 buckets, and 2 buckets of water in the vicinity of three waybill numbers, the average of the three is 7/3, which is about 2.3, and since the average has a small number, the next delivery amount of the barreled water is 3.

The step S200 of predicting the time required for next delivery of the bottled water by the user may be divided into steps S2a0 to S2C0, referring to fig. 3.

In step S2a0, the number of days consumed corresponding to the temperature at which the current temperature coincides is found out from a preset second database in which the number of the barreled water note, the average temperature of the barreled water from the completion of the delivery to the completion of the drinking of the corresponding note number, and the number of days consumed are stored, using the current temperature as a query object.

In step S2B0, the sum of the delivery amount of the waybill number with the temperature consistent with the current temperature is obtained from the first database as a dividend, and the daily average consumption amount of the current waybill number is obtained by taking the sum of the consumption days of the waybill number with the current temperature as a divisor;

in step S2C0, the total drinking time of the water in the waybill number at this time is calculated by using the current waybill number water distribution amount as a dividend and the current waybill number water daily average consumption as a divisor.

For example, when the current temperature is 30 degrees celsius, three groups of barreled water with the delivery volume of 3 barrels and the consumption days of 2 days are found in the second database, the average temperature consistent with the temperature of 30 degrees celsius is 30 degrees celsius, the delivery volume of the barreled water of the first group is 4 barrels and the consumption days of 3 days are found, the delivery volume of the barreled water of the third group is 5 barrels and the consumption days of 3 days are found, and then the daily average consumption at the temperature of 30 degrees celsius can be calculated to be 12 barrels/8 days, that is, 1.5 barrels per day, according to the calculation method of step S2B 0.

Then assuming that the delivery volume of the water in the current manifest number is 6 barrels, the total time taken to drink is predicted to be 4 days.

The analysis and calculation steps for the timing of sending the confirmation information to the mobile phone of the distribution address user mentioned in step S200 can be divided into steps S210 to S260, referring to fig. 4.

In step S210, based on the obtained delivery time of the user historical delivery frequency waybill number and the delivery completion time, the total actual delivery time of the corresponding waybill number barreled water is analyzed and calculated.

In step S220, the predicted delivery time of the corresponding waybill number is calculated by using the driving speed of the week in which the waybill number is located on the day, the delivery distance of the corresponding waybill number as a dividend, and the driving speed of the week in which the current day is located as a divisor from a preset third database in which the driving speeds of every day are stored, wherein the starting distance of the corresponding waybill number is the distance from the barreled water delivery location to the barreled water delivery address.

In step S230, based on the estimated delivery time and the actual delivery time of the waybill number, the actual delivery time is used as the decremented number, the estimated delivery time is used as the decremented number, and the delivery time difference is calculated;

in step S240, the average of the distribution time differences of the units adjacent to the three times is used as the expected distribution time difference of the next unit;

in step S250, the estimated delivery time of the next waybill number is calculated by using the delivery distance of the next waybill number as a dividend and the traveling speed of the day of the week as a divisor, and the estimated delivery time difference of the next waybill number is added to be used as the estimated delivery time of the next waybill number;

in step S260, the actual required time that the user needs the barreled water is analyzed from the total drinking time of the barreled water of the current waybill number, and a first preset time before the actual required time that the user needs the barreled water is taken as a suitable time for sending the confirmation information to the mobile phone of the delivery address user, where the first preset time is the predicted delivery time of the next waybill number.

For example, assuming that the time difference between the adjacent three orders is 10 minutes, 20 minutes and 30 minutes in sequence, the predicted delivery time difference of the next order is 20 minutes on the average of the three, assuming that the predicted delivery time of the next order is 1 hour, the predicted delivery time of the next order is 80 minutes, assuming that the time taken for the user to need barreled water is 4 days later, the notification time is 22 hours and 40 minutes on the third day.

Step S200 further includes a step of operating synchronously with the step of sending the confirmation information to the mobile phone of the delivery address user: and starting the voice prompt device to remind the user of the distribution address of voice dialing.

The voice prompt device mentioned in step S200 is a voice prompt.

In step S300, the information sent by the delivery address user is obtained for analysis, and the time and the amount of next required barreled water delivery by the delivery address user are confirmed and delivery arrangement is made based on the analyzed information.

The step of acquiring and analyzing the information sent by the distribution address user in step S300 can be divided into steps S3a0 to S3C0, see fig. 5.

In step S3a0, the information sent back by the delivery address user is acquired.

In step S3B0, the sum of the time period when the distribution address user receives the information and the current day and date is used as a first cipher group, a preset two-digit cipher is used as a second cipher group, if the first cipher group is a prime number, the second cipher group is located before the first cipher group, and if the first cipher group is a non-prime number, the second cipher group is located after the first cipher group.

The method comprises the steps of taking the delivery quantity of barreled water required by a delivery address user as first encrypted information, taking the delivery time of the barreled water required by the delivery address user as second encrypted information, wherein the first encrypted information is located between a first password group and a second password group, and the second encrypted information is located at the last position.

In step S3D0, the data and the position of the first password group and the second password group of the information sent back by the delivery address user are compared with the data and the position of the correct first password group and the correct second password group, and if the comparison is consistent, the first encryption information is extracted as the delivery quantity of the barreled water required by the delivery address user, and the second encryption information is extracted as the delivery time of the barreled water required by the delivery address user.

For example, assuming that the current date is 16, the time period when the delivery address user receives the information is 12, the first password set is 28, the second password set is 7, since the first password set is a non-prime number, the second password set is located behind the first password set, assuming that the delivery amount of the barreled water required by the user is 5, and the delivery time of the barreled water required by the user is 10, the formed information is 285710.

The embodiment of the application provides a computer readable storage medium, which comprises a program capable of being loaded and executed by a processor to realize the method in any one of the figures 1-5.

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 application concept, embodiments of the present application provide a barreled water delivery system, which includes a memory and a processor, where the memory stores a program that can be executed on the processor to implement any one of the methods shown in fig. 1 to 5.

It will be clear to those skilled in the art that, for convenience and simplicity of description, the foregoing division of the functional modules is merely used as an example, and in practical applications, the above function distribution may be performed by different functional modules according to needs, that is, the internal structure of the device is divided into different functional modules to perform all or part of the above described functions. For the specific working processes of the system, the apparatus and the unit described above, reference may be made to the corresponding processes in the foregoing method embodiments, and details are not described here again.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other manners. For example, the above-described apparatus embodiments are merely illustrative, and for example, a module or a unit may be divided into only one logical function, and may be implemented in other ways, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form.

Units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, and can also be realized in a form of a software functional unit.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application may be substantially implemented or contributed by the prior art, or all or part of the technical solution may be embodied in a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, a network device, or the like) or a processor (processor) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: u disk, removable hard disk, read only memory, random access memory, magnetic or optical disk, etc. for storing program codes.

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 (9)

1. A barreled water dispensing method, comprising:

acquiring a delivery address of the barreled water and a mobile phone number of a delivery address user;

analyzing and calculating a barreled water storage address closest to a corresponding delivery address to be taken as a barreled water delivery starting place based on historical barreled water delivery conditions of a delivery address user, predicting time and quantity of barreled water required by the delivery address user next time, analyzing and calculating a proper sending opportunity, sending prediction information of the time and quantity of barreled water required by the user next time to a mobile phone of the delivery address user for confirmation, wherein the historical barreled water delivery conditions of the delivery address user comprise historical barreled water delivery quantity of the delivery address user, delivery time of corresponding delivery quantity and delivery time of completing delivery;

and acquiring the information sent by the distribution address user for analysis, confirming the time and the quantity of barreled water required by the distribution address user next time based on the analyzed information, and making distribution arrangement.

2. The barreled water distribution method according to claim 1, wherein the analyzing and calculating step of the storage address of the barreled water closest to the corresponding distribution address is as follows: and planning a path from each barreled water storage position to the barreled water distribution address and acquiring a corresponding path by taking the barreled water distribution address as a starting point and taking the preset barreled water storage positions as end points one by one, and selecting the barreled water storage position corresponding to the shortest path as a barreled water distribution starting place of the corresponding distribution address.

3. The barreled water distribution method according to claim 1, wherein the confirmation step of predicting the next required barreled water distribution amount of the user is as follows:

searching out the historical barreled water delivery waybill number of the delivery address user, the delivery amount of the barreled water of the corresponding waybill number, the delivery time of the barreled water of the corresponding waybill number and the delivery finishing time from a first database in which the historical barreled water delivery waybill number of the user, the delivery amount of the barreled water of the corresponding waybill number and the delivery finishing time of the corresponding waybill number are stored;

the barreled water amount that the delivery address user was close to the delivery of cubic waybill number is obtained and the average value is taken as the next required barreled water delivery volume of user, if there is the decimal in the average value then gets rid of the decimal and adds 1 as the prediction delivery volume of next barreled water.

4. The barreled water dispensing method according to claim 3, wherein the confirmation step of predicting the time required for next barreled water dispensing by the user is as follows:

searching for the consumption days corresponding to the temperature consistent with the current temperature by taking the current temperature as an inquiry object from a preset second database in which the barreled water waybill number, the average temperature of the barreled water in the period from the completion of the distribution to the completion of the drinking of the corresponding waybill number and the consumption days are stored;

acquiring the sum of the delivery amount of the order number with the temperature consistent with the current temperature from a first database as a dividend, and acquiring the daily average consumption of the current order number by taking the sum of the consumption days of the order number with the temperature consistent with the current temperature as a divisor;

with No. bottled water delivery volume of current waybill as dividend, No. bottled water's daily average consumption of current waybill is as the divisor, calculates this No. bottled water of waybill's drink total consuming time.

5. The barreled water dispensing method according to claim 4, wherein: the analysis and calculation steps of the proper time for sending the confirmation information to the mobile phone of the distribution address user are as follows:

analyzing and calculating the actual total delivery time of the barreled water of the corresponding waybill number based on the obtained delivery time of the waybill number of the user historical delivery frequency and the delivery completion time;

calculating the predicted delivery time consumption of the corresponding waybill number by taking the driving speed of the week number where the waybill number is located on the current day, the delivery distance of the corresponding waybill number as a dividend and the driving speed of the week number where the current day is located as a divisor from a preset third database in which the driving speed of each week is stored, wherein the delivery distance of the corresponding waybill number is the distance from the barreled water delivery starting place to the barreled water delivery address;

based on the estimated distribution time consumption and the actual distribution time consumption of the waybill number, calculating a distribution time difference by taking the actual distribution time consumption as a subtracted number and the estimated distribution time consumption as a subtracted number;

taking the average value of the distribution time difference of the unit numbers close to the third time as the predicted distribution time difference of the next unit number;

taking the distribution distance of the next order number as a dividend, taking the traveling speed of the week of the current day as a divisor, calculating the predicted distribution time consumption of the next order number, and adding the predicted distribution time difference of the previous and next order numbers to be used as the predicted distribution time consumption of the next order number;

the actual required time of the user needing the barreled water is analyzed according to the total drinking time of the barreled water of the current waybill number, the first preset time before the actual required time of the user needing the barreled water is used as the proper time for sending confirmation information to the mobile phone of the delivery address user, and the first preset time is the predicted delivery time of the next waybill number.

6. The barreled water dispensing method of claim 1, further comprising the step of operating in synchronization with sending a confirmation message to a delivery address user's handset: and starting the voice prompt device to remind the user of the distribution address of voice dialing.

7. The barreled water distribution method according to claim 1, wherein the steps of sending back information acquisition and resolution by a distribution address user are as follows:

acquiring information sent back by a distribution address user;

taking the sum of the time period when the distribution address user receives the information and the date of the day as a first cipher group, taking a preset two-digit digital cipher as a second cipher group, and if the first cipher group is a prime number, the second cipher group is positioned before the first cipher group, and if the first cipher group is a non-prime number, the second cipher group is positioned behind the first cipher group;

taking the delivery quantity of the barreled water required by the delivery address user as first encrypted information, taking the delivery time of the barreled water required by the delivery address user as second encrypted information, wherein the first encrypted information is positioned between the first password group and the second password group, and the second encrypted information is positioned at the last position;

and comparing the data and the positions of the first password group and the second password group of the information sent back by the delivery address user with the data and the positions of the correct first password group and the correct second password group, if the comparison is consistent, extracting the first encrypted information as the delivery quantity of the barreled water required by the delivery address user, and extracting the second encrypted information as the delivery time of the barreled water required by the delivery address user.

8. The utility model provides a bottled water delivery system which characterized in that: 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 the method of dispensing bottled water as claimed in any one of claims 1 to 7.

9. A computer storage medium, characterized in that: a program that is loadable by a processor and that when executed implements the barreled water dispensing method according to any one of claims 1 to 7.

Images