CN113793078A - Method and device for determining hydrogen energy demand in holidays and storage medium - Google Patents

Abstract

The application relates to a method, a device and a storage medium for determining the demand of hydrogen energy in holidays, wherein the method comprises the following steps: the method comprises the steps of obtaining a first travel plan of a target object on a holiday, wherein the target object is any resident object in a target area. And acquiring a first residual energy quantity of the target object, and determining a first energy demand quantity of the target object according to the first trip plan. Determining a first amount of hydrogen to be added to the target object based on the first amount of energy demand and the first amount of remaining energy. According to the first hydrogenation amounts of all target objects in the target area, the hydrogen energy demand of the target area on holidays can be more accurately determined, and the hydrogen energy demand is sent to a hydrogen production plant, so that the hydrogen production plant can prepare hydrogen energy according to the hydrogen energy demand, and the inconvenience in trip of people due to the fact that the hydrogen energy is prepared too little in holidays is avoided.

Description

Method and device for determining hydrogen energy demand in holidays and storage medium

Technical Field

The application relates to the technical field of new energy, in particular to a method and a device for determining the demand of a hydrogen energy source in holidays, festivals and holidays and a storage medium.

Background

At present, the fusion of new energy vehicles and big data is a great trend, and intelligent new energy vehicles based on big data will be the key direction for transformation and upgrading of the automobile industry. However, research finds that the existing determination of the hydrogen energy demand of a certain area mainly includes hydrogen energy preparation according to the demand reported by each hydrogenation station, but each hydrogenation station also determines how much hydrogen energy is needed according to experience and the respective hydrogen energy stock, so that the hydrogen energy demand of the area cannot be accurately predicted, and particularly, many people can play on holidays and more cannot accurately predict the hydrogen energy demand of the area.

Disclosure of Invention

In view of the above, it is necessary to provide a holiday hydrogen energy demand determination method, a holiday hydrogen energy demand determination device and a storage medium, which can accurately predict the hydrogen energy demand, in view of the above technical problems.

A holiday hydrogen energy demand determination method, the method comprising:

acquiring a first travel plan of a target object on a holiday; wherein the target object is any resident object in the target area;

acquiring a first residual energy amount of the target object;

determining a first energy demand of the target object according to the first travel plan;

determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

In one embodiment, the obtaining of the first travel plan of the target subject on holidays includes:

crawling first travel information of the target object;

and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

In one embodiment, the first travel plan includes a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area;

the determining a first amount of hydrogen for the target object based on the first amount of energy demand and the first amount of remaining energy includes:

obtaining a first energy price of the target area and a second energy price of the destination;

comparing the magnitude of the first energy price and the second energy price;

if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

In one embodiment, the determining the hydrogen energy demand of the target region on holidays according to the first hydrogenation amounts of all target objects in the target region comprises:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

In one embodiment, the method further comprises:

acquiring a second travel plan of the foreign object from the foreign area to the target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

obtaining a second remaining energy amount of the foreign object;

determining a second energy demand of the foreign object according to the second travel plan;

obtaining a third energy price for the foreign region;

determining a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second remaining energy amount and the third energy price;

counting a second accumulated value of a second hydrogenation amount of each foreign object in the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value, the second accumulated value and the region residual energy quantity.

In one embodiment, the second travel plan includes an origin; the second energy demand of the foreign object comprises a fourth demand of the foreign object from the origin to the target area and a fifth demand for traveling in the target area;

the determining a second amount of hydrogen added by the foreign object in the target area according to the second amount of energy demand, the second amount of remaining energy and the third energy price includes:

comparing the magnitude of the first energy price and the third energy price;

if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand;

comparing the third accumulated value with the second remaining energy amount;

if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value;

and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area.

In one embodiment, the method further comprises:

if the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount;

and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

In one embodiment, the method further comprises:

and if the first energy price is smaller than the third energy price and the second remaining energy amount is smaller than the fourth demand, taking the sum of the maximum hydrogenation capacity of the target object and the fifth demand as a second hydrogenation amount of the foreign object in the target area.

A holiday hydrogen energy demand determination apparatus, the apparatus comprising:

the first travel plan acquisition module is used for acquiring a first travel plan of the target object on holidays; wherein the target object is any resident object in the target area;

the first residual energy quantity obtaining module is used for obtaining a first residual energy quantity of the target object;

a first energy demand determination module, configured to determine a first energy demand of the target object according to the first travel plan;

a first hydrogenation amount determination module for determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and the hydrogen energy source demand determining module is used for determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned method.

The method, the device, the computer equipment and the storage medium for determining the hydrogen energy demand in holidays comprise the following steps: the method comprises the steps of obtaining a first travel plan of a target object on a holiday, wherein the target object is any resident object in a target area. And acquiring a first residual energy quantity of the target object, and determining a first energy demand quantity of the target object according to the first trip plan. Determining a first amount of hydrogen to be added to the target object based on the first amount of energy demand and the first amount of remaining energy. And determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area. The first energy demand of the target object is determined according to the first trip plan of the target object on holidays, the hydrogen energy demand of the target area on holidays can be determined according to the first energy demand and the first residual energy, the first trip plan of the target object is taken into consideration, the hydrogen energy demand of the target area on holidays can be more accurately determined, the hydrogen energy demand is sent to a hydrogen production plant, the hydrogen production plant is enabled to produce hydrogen energy according to the hydrogen energy demand, too little hydrogen energy production in holidays is avoided, and people are enabled to have inconvenience in trip.

Drawings

FIG. 1 is a schematic flow chart of a method for determining the amount of hydrogen energy required for holidays in one embodiment;

FIG. 2 is a block diagram showing the construction of a hydrogen energy demand determining apparatus for holidays and festivals in one embodiment;

FIG. 3 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In one embodiment, as shown in fig. 1, there is provided a holiday hydrogen energy demand determination method, comprising the steps of:

step S101: acquiring a first travel plan of a target object on a holiday; wherein the target object is any resident object in the target area;

wherein, the holidays are holidays of five-one and eleven festivals and the like. The target area is a county or a city. The target object is any resident object in the target area, and the travel track of the user can be analyzed through big data so as to determine whether the object is a resident object, and if the object is a resident object, the object is taken as the target object.

Crawling first travel information of the target object; and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

For example, holidays are eleven because everyone plans attractions and bookings in advance before going out, usually half a month or 1 month in advance. Therefore, search browsing data of a target object on an application program such as the internet or a cosmos, a trip and the like in a preset time period (for example, 9-25 days) before holidays are crawled, and the search browsing data is analyzed and filtered to obtain trip information about trips. For example, the search browsing data is matched with preset keywords (e.g., scenic spots, hotels, gourmets, etc.), so as to determine the first travel information. And analyzing the first travel information, and determining the destination of the target object, thereby determining a first travel plan of the target object on holidays. After the destination is determined, the first travel information can be determined by combining the travel information of the target object and the travel route recommended on the internet.

It should be noted that crawling the first travel information of the target object, analyzing the first travel information, and determining the first travel plan of the target object on holidays all belong to the common technical means of data crawling and large data mining analysis, and therefore, details are not described here.

Step S102, acquiring a first residual energy quantity of the target object;

wherein the first remaining energy amount is a remaining energy amount of the target object (the target object herein may refer to the target vehicle).

Step S103, determining a first energy demand of the target object according to the first trip plan;

in the embodiment of the invention, big data mining analysis is carried out on the first trip plan, and the first energy demand of the target object is determined. Wherein the first travel plan includes a destination, for example, the target area is inner Mongolia and the destination is Beijing. The first energy demand includes a first demand of the target object from the target area (inner Mongolia) to the destination (Beijing), a second demand for traveling at the destination (Beijing), and a third demand for returning from the destination (Beijing) to the target area (inner Mongolia). The second demand of the trip at the destination (Beijing) can be determined by mining and analyzing the search and browse data of the target object and tourist attractions and restaurants recommended by the public, wherein the second demand is only an estimated value.

It should be noted that, the existing big data mining analysis technology is used for analysis here to determine the first energy demand, which is not described in detail herein.

Step S104, determining a first hydrogenation amount of the target object according to the first energy demand and the first residual energy amount;

in the embodiment of the invention, the first energy demand and the first residual energy are compared and analyzed to determine whether hydrogenation is needed in the target area, and the first hydrogenation amount of the target object in the target area is determined.

Alternatively, a first energy price of the target area and a second energy price of the destination may be acquired, and the first amount of hydrogenation of the target object may be determined based on the first energy price, the second energy price, the first energy demand, and the first remaining energy amount. For example, based on the first energy price and the second energy price, it can be determined whether it is cheaper to hydrogenate at the target area or the destination, thereby selecting a location where the hydrogenation is cheaper, and typically the user will have a lot of hydrogen energy at the cheaper location. Through introducing the energy price, thereby can more accurately predict the hydrogen energy demand of target area on holidays, send the hydrogen energy demand to hydrogen manufacturing plant for hydrogen manufacturing plant prepares the hydrogen energy according to the hydrogen energy demand, avoids preparing the hydrogen energy too little in holidays, makes people go out inconveniently.

Step S105, determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

In the embodiment of the invention, the first hydrogenation amounts of all target objects in the target area are accumulated, and the accumulated sum is used as the hydrogen energy demand of the target area on holidays.

The method for determining the hydrogen energy demand in holidays comprises the following steps: the method comprises the steps of obtaining a first travel plan of a target object on a holiday, wherein the target object is any resident object in a target area. And acquiring a first residual energy quantity of the target object, and determining a first energy demand quantity of the target object according to the first trip plan. Determining a first amount of hydrogen to be added to the target object based on the first amount of energy demand and the first amount of remaining energy. And determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area. The first energy demand of the target object is determined according to the first trip plan of the target object on holidays, the hydrogen energy demand of the target area on holidays can be determined according to the first energy demand and the first residual energy, the first trip plan of the target object is taken into consideration, the hydrogen energy demand of the target area on holidays can be more accurately determined, the hydrogen energy demand is sent to a hydrogen production plant, the hydrogen production plant is enabled to produce hydrogen energy according to the hydrogen energy demand, too little hydrogen energy production in holidays is avoided, and people are enabled to have inconvenience in trip.

Optionally, the first travel plan comprises a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area;

the determining a first amount of hydrogen for the target object based on the first amount of energy demand and the first amount of remaining energy includes:

a first step of acquiring a first energy price of the target area and a second energy price of the destination;

a second step of comparing the first energy price and the second energy price;

thirdly, if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and fourthly, if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

Wherein, the steps are not in fixed sequence and can be executed simultaneously.

In an embodiment of the present invention, the first energy price of the target area may be an average energy price or a lowest energy price of the target area. The second energy price for the destination may be an average energy price or a lowest energy price for the destination. Comparing the first energy price with the second energy price, if the first energy price is less than the second energy price, the method indicates that the hydrogenation is proper in the target area and is improper in the destination. Therefore, the vehicle to be targeted may be charged with the hydrogen energy source immediately before the departure to the destination. And subtracting the difference value of the first residual energy quantity from the maximum hydrogenation capacity of the vehicle of the target object to be used as the first hydrogenation quantity of the target object in the target area.

If the first energy price is greater than the second energy price, it means that the hydrogenation is inexpensive and appropriate at the destination and that the hydrogenation is inappropriate in the target area. However, it is necessary to further compare the first remaining energy amount and the first required amount of the target object to determine the first hydrogenation amount of the target object in the target area, rather than directly considering that the target object is not hydrogenated in the target area because the destination hydrogenation is cheaper. Therefore, if the first remaining energy amount is smaller than the first required amount, or the first remaining energy amount is smaller than a preset threshold (the preset threshold represents a driving critical value, for example, only 10 km can be driven), the target object still needs to be hydrogenated in the target area, and the target object can be ensured to be driven to the destination.

Therefore, if the first energy price is greater than the second energy price and the first remaining energy amount of the target object is greater than the first demand, it means that the remaining energy amount of the target object can be driven to the destination, and the first hydrogenation amount of the target object in the target area is determined to be any value between 0 and one half of the first demand.

If the first energy price is greater than the second energy price and the first remaining energy amount of the target object is less than the first demand amount, it means that the target object cannot be directly driven to the destination if the target object is not hydrogenated before the departure. And taking a first difference value between the first demand amount and the first residual energy amount as a first hydrogenation amount of the target object in the target area. Ensuring that the target object can be driven to the destination. Wherein the first hydrogenation amount of the target object in the target region may be any value greater than the first difference.

Optionally, the determining the hydrogen energy demand of the target region on holidays according to the first hydrogen addition amounts of all target objects in the target region includes:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

In the embodiment of the invention, through the first step to the fourth step, the first hydrogenation amount of each target object in the target area is determined, and the first accumulated values of the first hydrogenation amounts of all the target objects in the target area are counted. And counting the regional residual energy quantity of the target region. And comparing the first accumulated value with the regional residual energy quantity, wherein if the first accumulated value is smaller than the regional residual energy quantity, the target region does not need to prepare hydrogen energy on holidays and festivals, and the hydrogen energy is sufficient. And if the first accumulated value is larger than the regional residual energy quantity, taking the difference value between the first accumulated value and the regional residual energy quantity as the quantity to be prepared. The to-be-prepared quantity is sent to the hydrogen production plant, so that the hydrogen production plant can prepare hydrogen energy according to the to-be-prepared quantity, and the inconvenience of people in going out due to the fact that the hydrogen energy is prepared too little in holidays is avoided.

Optionally, the method further comprises:

the method comprises the following steps of firstly, acquiring a second trip plan of a foreign object from a foreign area to a target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

in the embodiment of the present invention, for the above-described embodiment, the target area is beijing, and the foreign object is a visitor played by a foreign area (e.g., west ampere, down mountain, etc.) in beijing. The second travel plan is a travel plan from the foreign area to beijing. The determination method of the second trip plan is the same as the determination method of the first trip plan, and the existing big data mining analysis technology is used, which is not described herein again.

A second step of obtaining a second remaining energy amount of the foreign object;

thirdly, determining a second energy demand of the foreign object according to the second trip plan;

in an embodiment of the invention, a second remaining energy amount of the foreign object is obtained, and a second energy demand amount of the foreign object is determined according to the second travel plan. And carrying out big data mining analysis on the second trip plan to determine a second energy demand of the foreign object.

Wherein the second travel plan includes an origin, where the target area is beijing and the origin is west 'an, down's mountain, etc., according to the example of the above embodiment. The second energy demand includes a fourth demand for the foreign object from the origin to the target area and a fifth demand for travel at the target area. The fifth demand for travel can be determined by mining and analyzing the search and browsing data of the external object and the tourist attractions and restaurants recommended by the public, wherein the fifth demand is only an estimated value.

It should be noted that, the second energy demand is determined by performing analysis by using the existing big data mining analysis technology, which is not described in detail herein.

Fourthly, acquiring a third energy price of the foreign area;

fifthly, determining a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second residual energy amount and the third energy price;

in an embodiment of the invention, comparing the magnitude of said first energy price and said third energy price; if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand; comparing the third accumulated value with the second remaining energy amount; if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value; and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area. If the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount; and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

In the embodiment of the present invention, if the first energy price is less than the third energy price, it means that the hydrogenation is inexpensive and suitable in the target area and that the hydrogenation is not suitable at the beginning. However, it is necessary to further compare the magnitude of the second remaining energy amount with the magnitude of the fourth demand. If the first energy price is less than the third energy price and the second remaining energy amount is greater than the fourth demand amount, it indicates that the foreign object can be driven to the target area without being initially hydrogenated. And obtaining a third accumulated value of the fourth demand and the fifth demand, comparing the third accumulated value with the second residual energy quantity, if the second residual energy quantity is larger than the third accumulated value, indicating that the external object has residual energy quantity after playing Beijing, obtaining a second difference value of the second residual energy quantity and the third accumulated value, wherein the second difference value is the residual energy quantity of the external object after playing Beijing, and taking the difference value between the maximum hydrogenation capacity (the maximum hydrogenation capacity specified by the vehicle) of the target object and the second difference value as the second hydrogenation quantity of the external object in the target area.

If the second residual energy amount is smaller than the third accumulated value, the fact that the residual energy amount of the foreign object is not enough for the foreign object to play in Beijing is indicated, hydrogenation is needed in the playing process, a third difference value between the third accumulated value and the second residual energy amount is obtained, and the sum of the maximum hydrogenation capacity of the target object and the third difference value is used as a second hydrogenation amount of the foreign object in the target area. For convenience of understanding, it is illustrated here that the maximum hydrogenation capacity is 400, the second remaining energy amount is 50, the fourth demand amount is 30, the fifth demand amount is 90, the third accumulated value is 120, the remaining energy amount of the foreign object is not enough for the foreign object to play in beijing, a third difference between the third accumulated value 120 and the second remaining energy amount 50 is obtained, and the third difference is 70, which indicates that the foreign object still needs to be hydrogenated 70 when playing in beijing. In addition, since hydrogenation is cheaper in Beijing, the foreign object is generally filled with hydrogen energy before leaving Beijing, and therefore, the sum of the maximum hydrogenation capacity of the target object and the third difference is used as the second hydrogenation amount of the foreign object in the target area.

Wherein if the first energy price is less than the third energy price and the second remaining energy amount is less than the fourth demand, the sum of the maximum hydrogenation capacity of the target object and the fifth demand is used as the second hydrogenation amount of the foreign object in the target area.

In embodiments of the invention where the second remaining energy amount is less than the fourth demand, this means that the foreign object cannot go directly to the target area without being hydrogenated at the origin. Therefore, it can be considered that the foreign object is initially hydrogenated, and the residual energy amount after hydrogenation is just greater than or equal to the fourth demand amount, for example, the difference between the residual energy amount after hydrogenation and the fourth demand amount is greater than a preset threshold value, and the preset threshold value is a value of 0 or less, which is determined according to actual conditions. Then, the sum of the maximum hydrogenation capacity of the target object and the fifth required amount is used as the second hydrogenation amount of the target region.

In the embodiment of the invention, through the steps, the second hydrogenation amount of each foreign object in the target area is determined, and the second accumulated values of the second hydrogenation amounts of all the foreign objects in the target area are counted. In the embodiment, a first accumulated value of a first hydrogenation amount of the target object in the target area is counted, and the hydrogen energy demand of the target area on holidays is determined according to the first accumulated value, the second accumulated value and the area residual energy amount. Specifically, the sum of the first accumulated value and the second accumulated value is compared with the area residual energy amount, and if the sum is smaller than the area residual energy amount, the target area does not need to produce hydrogen energy on holidays and the hydrogen energy is sufficient. And if the sum is larger than the residual energy quantity of the region, taking the difference between the sum and the residual energy quantity of the region as the quantity to be prepared. The to-be-prepared quantity is sent to the hydrogen production plant, so that the hydrogen production plant can prepare hydrogen energy according to the to-be-prepared quantity, and the inconvenience of people in going out due to the fact that the hydrogen energy is prepared too little in holidays is avoided.

It should be understood that, although the steps in the flowchart of fig. 1 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least a portion of the steps in fig. 1 may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed in turn or alternately with other steps or at least a portion of the other steps or stages.

In one embodiment, as shown in fig. 2, there is provided a holiday hydrogen energy demand determination device including:

the first travel plan acquisition module is used for acquiring a first travel plan of the target object on holidays; wherein the target object is any resident object in the target area;

the first residual energy quantity obtaining module is used for obtaining a first residual energy quantity of the target object;

a first energy demand determination module, configured to determine a first energy demand of the target object according to the first travel plan;

a first hydrogenation amount determination module for determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and the hydrogen energy source demand determining module is used for determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

In one optional embodiment, the first travel plan obtaining module is specifically configured to:

crawling first travel information of the target object;

and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

In one optional embodiment, the first travel plan includes a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area; the first hydrogenation amount determination module is specifically configured to:

obtaining a first energy price of the target area and a second energy price of the destination;

comparing the magnitude of the first energy price and the second energy price;

if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

In one optional embodiment, the hydrogen energy demand determination module is specifically configured to:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

In one optional embodiment, the holiday-festival hydrogen energy demand determination device further comprises a second trip plan obtaining module, a second remaining energy obtaining module, a second energy demand determination module, a third energy price obtaining module and a second hydrogenation amount determination module;

the second travel plan acquisition module is used for acquiring a second travel plan of the foreign object from the foreign area to the target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

the second residual energy quantity obtaining module is used for obtaining a second residual energy quantity of the foreign object;

a second energy demand determination module, configured to determine a second energy demand of the foreign object according to the second travel plan;

a third energy price acquisition module for acquiring a third energy price of the foreign area;

a second hydrogenation amount determination module, configured to determine a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second remaining energy amount, and the third energy price;

the hydrogen energy source demand quantity determining module is used for counting a second accumulated value of a second hydrogenation quantity of each foreign object in the target area; and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value, the second accumulated value and the region residual energy quantity.

In one optional embodiment, the second travel plan includes an origin; the second energy demand of the foreign object comprises a fourth demand of the foreign object from the origin to the target area and a fifth demand for traveling in the target area; the second hydrogenation amount determination module is specifically configured to:

comparing the magnitude of the first energy price and the third energy price;

if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand;

comparing the third accumulated value with the second remaining energy amount;

if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value;

and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area.

In an optional embodiment, the second hydrogenation amount determining module is specifically configured to:

if the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount;

and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

In an optional embodiment, the second hydrogenation amount determining module is specifically configured to:

and if the first energy price is smaller than the third energy price and the second remaining energy amount is smaller than the fourth demand, taking the sum of the maximum hydrogenation capacity of the target object and the fifth demand as a second hydrogenation amount of the foreign object in the target area.

For the specific limitations of the holiday hydrogen energy source demand determination device, reference may be made to the above limitations of the holiday hydrogen energy source demand determination method, which are not described herein again. All or part of each module in the holiday hydrogen energy demand determination device can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a server, the internal structure of which may be as shown in fig. 3. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the computer device is used for storing freight vehicle related data, hydrogenerator related data and intermediate station and road related data. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a holiday hydrogen energy demand determination method.

Those skilled in the art will appreciate that the architecture shown in fig. 3 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is provided, comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing the following steps when executing the computer program:

acquiring a first travel plan of a target object on a holiday; wherein the target object is any resident object in the target area;

acquiring a first residual energy amount of the target object;

determining a first energy demand of the target object according to the first travel plan;

determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

In one embodiment, the processor, when executing the computer program, further performs the steps of:

crawling first travel information of the target object;

and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

In one embodiment, the first travel plan includes a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area; the processor, when executing the computer program, further performs the steps of:

obtaining a first energy price of the target area and a second energy price of the destination;

comparing the magnitude of the first energy price and the second energy price;

if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

In one embodiment, the processor, when executing the computer program, further performs the steps of:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

In one embodiment, the processor, when executing the computer program, further performs the steps of:

acquiring a second travel plan of the foreign object from the foreign area to the target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

obtaining a second remaining energy amount of the foreign object;

determining a second energy demand of the foreign object according to the second travel plan;

obtaining a third energy price for the foreign region;

determining a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second remaining energy amount and the third energy price;

counting a second accumulated value of a second hydrogenation amount of each foreign object in the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value, the second accumulated value and the region residual energy quantity.

In one embodiment, the second travel plan includes an origin; the second energy demand of the foreign object comprises a fourth demand of the foreign object from the origin to the target area and a fifth demand for traveling in the target area; the processor, when executing the computer program, further performs the steps of:

comparing the magnitude of the first energy price and the third energy price;

if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand;

comparing the third accumulated value with the second remaining energy amount;

if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value;

and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area.

In one embodiment, the processor, when executing the computer program, further performs the steps of:

if the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount;

and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

In one embodiment, the processor, when executing the computer program, further performs the steps of:

and if the first energy price is smaller than the third energy price and the second remaining energy amount is smaller than the fourth demand, taking the sum of the maximum hydrogenation capacity of the target object and the fifth demand as a second hydrogenation amount of the foreign object in the target area.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of:

acquiring a first travel plan of a target object on a holiday; wherein the target object is any resident object in the target area;

acquiring a first residual energy amount of the target object;

determining a first energy demand of the target object according to the first travel plan;

determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

In one embodiment, the computer program when executed by the processor further performs the steps of:

crawling first travel information of the target object;

and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

In one embodiment, the first travel plan includes a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area; the computer program when executed by the processor further realizes the steps of:

obtaining a first energy price of the target area and a second energy price of the destination;

comparing the magnitude of the first energy price and the second energy price;

if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

In one embodiment, the computer program when executed by the processor further performs the steps of:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

In one embodiment, the computer program when executed by the processor further performs the steps of:

acquiring a second travel plan of the foreign object from the foreign area to the target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

obtaining a second remaining energy amount of the foreign object;

determining a second energy demand of the foreign object according to the second travel plan;

obtaining a third energy price for the foreign region;

determining a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second remaining energy amount and the third energy price;

counting a second accumulated value of a second hydrogenation amount of each foreign object in the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value, the second accumulated value and the region residual energy quantity.

In one embodiment, the second travel plan includes an origin; the second energy demand of the foreign object comprises a fourth demand of the foreign object from the origin to the target area and a fifth demand for traveling in the target area; the computer program when executed by the processor further realizes the steps of:

comparing the magnitude of the first energy price and the third energy price;

if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand;

comparing the third accumulated value with the second remaining energy amount;

if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value;

and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area.

In one embodiment, the computer program when executed by the processor further performs the steps of:

if the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount;

and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

In one embodiment, the computer program when executed by the processor further performs the steps of:

and if the first energy price is smaller than the third energy price and the second remaining energy amount is smaller than the fourth demand, taking the sum of the maximum hydrogenation capacity of the target object and the fifth demand as a second hydrogenation amount of the foreign object in the target area.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A method for determining hydrogen energy demand for holidays, and festivals, the method comprising:

acquiring a first travel plan of a target object on a holiday; wherein the target object is any resident object in the target area;

acquiring a first residual energy amount of the target object;

determining a first energy demand of the target object according to the first travel plan;

determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

2. The method for determining hydrogen energy demand for holidays according to claim 1, wherein the obtaining a first travel plan of the target object on holidays comprises:

crawling first travel information of the target object;

and analyzing the first travel information, and determining a first travel plan of the target object on a holiday.

3. The holiday hydrogen energy demand determination method according to claim 1, characterized in that the first travel plan includes a destination; the first energy demand of the target object comprises a first demand of the target object from the target area to the destination, a second demand for travel at the destination, and a third demand for return from the destination to the target area;

the determining a first amount of hydrogen for the target object based on the first amount of energy demand and the first amount of remaining energy includes:

obtaining a first energy price of the target area and a second energy price of the destination;

comparing the magnitude of the first energy price and the second energy price;

if the first energy price is larger than the second energy price and the first remaining energy quantity of the target object is larger than the first demand, determining that the first hydrogenation quantity of the target object in the target area is any value between 0 and one half of the first demand;

and if the first energy price is larger than the second energy price and the first residual energy quantity of the target object is smaller than the first demand, taking a first difference value between the first demand and the first residual energy quantity as a first hydrogenation quantity of the target object in the target area.

4. The method according to claim 3, wherein the determining the hydrogen energy demand of the target region on holidays based on the first hydrogenation amounts of all target objects in the target region comprises:

counting a first accumulated value of a first hydrogenation amount of each target object in the target area;

counting the residual energy quantity of the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value and the region residual energy quantity.

5. The holiday hydrogen energy demand determination method according to claim 4, characterized by further comprising:

acquiring a second travel plan of the foreign object from the foreign area to the target area; wherein the foreign object is any resident object in the foreign area; the foreign region is other than the target region;

obtaining a second remaining energy amount of the foreign object;

determining a second energy demand of the foreign object according to the second travel plan;

obtaining a third energy price for the foreign region;

determining a second hydrogenation amount of the foreign object in the target area according to the second energy demand, the second remaining energy amount and the third energy price;

counting a second accumulated value of a second hydrogenation amount of each foreign object in the target area;

and determining the hydrogen energy demand of the target region on holidays according to the first accumulated value, the second accumulated value and the region residual energy quantity.

6. The holiday hydrogen energy demand determination method of claim 5, wherein the second travel plan includes an origin; the second energy demand of the foreign object comprises a fourth demand of the foreign object from the origin to the target area and a fifth demand for traveling in the target area;

the determining a second amount of hydrogen added by the foreign object in the target area according to the second amount of energy demand, the second amount of remaining energy and the third energy price includes:

comparing the magnitude of the first energy price and the third energy price;

if the first energy price is smaller than the third energy price and the second remaining energy amount is larger than the fourth demand, acquiring a third accumulated value of the fourth demand and the fifth demand;

comparing the third accumulated value with the second remaining energy amount;

if the second residual energy quantity is larger than the third accumulated value, acquiring a second difference value between the second residual energy quantity and the third accumulated value;

and taking the difference value between the maximum hydrogenation capacity of the target object and the second difference value as the second hydrogenation amount of the foreign object in the target area.

7. The holiday hydrogen energy demand determination method according to claim 6, characterized by further comprising:

if the second remaining energy amount is less than the third accumulated value, obtaining a third difference value between the third accumulated value and the second remaining energy amount;

and taking the sum of the maximum hydrogenation capacity of the target object and the third difference value as a second hydrogenation amount of the foreign object in the target area.

8. The holiday hydrogen energy demand determination method according to claim 7, characterized by further comprising:

and if the first energy price is smaller than the third energy price and the second remaining energy amount is smaller than the fourth demand, taking the sum of the maximum hydrogenation capacity of the target object and the fifth demand as a second hydrogenation amount of the foreign object in the target area.

9. A holiday hydrogen energy demand determination device, characterized in that the device comprises:

the first travel plan acquisition module is used for acquiring a first travel plan of the target object on holidays; wherein the target object is any resident object in the target area;

the first residual energy quantity obtaining module is used for obtaining a first residual energy quantity of the target object;

a first energy demand determination module, configured to determine a first energy demand of the target object according to the first travel plan;

a first hydrogenation amount determination module for determining a first hydrogenation amount of the target object according to the first energy demand and the first remaining energy amount;

and the hydrogen energy source demand determining module is used for determining the hydrogen energy source demand of the target area on holidays according to the first hydrogenation amounts of all target objects in the target area.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 8.

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