CN114819853A - A system and method for intelligent delivery of spare parts for a new energy power station - Google Patents

Abstract

The invention is applicable to the computer field, and provides an intelligent delivery system and method for spare parts of a new energy power station, including: generating delivery data for the spare parts according to the obtained order information and specific use demand information, wherein the spare parts used for delivery to the transit address are the first A spare part, the second spare part is used for delivery to the terminal address, wherein the weight and/or volume of the first spare part is smaller than that of the second spare part, and each transit address is used to be shared by at least two terminal addresses; obtain the first spare part Spare part information associated with all existing use in the second spare part, and mark at least two spare parts associated with combined use as combined spare parts; determine whether the proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion In contrast, the present invention has the beneficial effects of providing a delivery guarantee for the assembly of combined spare parts installed in a wind farm, improving the safety factor, and facilitating access to auxiliary parts.

Description

A system and method for intelligent delivery of spare parts for a new energy power station

technical field

The invention belongs to the field of computers, and in particular relates to an intelligent delivery system and method for spare parts of a new energy power station.

Background technique

The development of new energy sources such as wind power and photovoltaics is an ideal way to overcome the problems of energy consumption and greenhouse gas emissions. In recent years, with the increasing demand for new energy, technologies such as wind power and photovoltaic power generation have developed rapidly, and the installed capacity of new energy has increased exponentially year by year. , according to the National Renewable Energy Law, new energy sources including wind power and photovoltaic power generation should be prioritized for power regulation. The phenomenon of abandoned light is still very serious. How to give full play to the advantages of new energy while taking into account its negative impact on the system, the scientific power generation scheduling for new energy has become the focus of current research.

In order to ensure the long-term normal operation of production, new energy power plants need to prepare spare parts for related components in the process of use. For example, wind power is the main equipment in the field of new energy. In the process of implementing condition maintenance, the management of spare parts is particularly important. It is necessary to ensure the normal operation of wind power for a long time, and spare parts need to be delivered and inspected after the customized or non-customized production is completed.

However, in the prior art, when the customized or non-customized production of spare parts is completed, it takes a certain amount of time for delivery. When the delivery time is before the delivery date, sometimes it is delivered during a single delivery and transportation. The quantity is fixed, and the delivery is often irregular. Therefore, an intelligent delivery system and method of spare parts for new energy power plants are proposed.

SUMMARY OF THE INVENTION

The purpose of the embodiments of the present invention is to provide a system and method for intelligent delivery of spare parts of a new energy power station, which is aimed at solving the problems raised in the above background art.

The embodiments of the present invention are implemented as follows. On the one hand, a method for intelligently delivering spare parts for a new energy power station, the method includes the following steps:

Generate delivery data for the spare parts according to the obtained order information and specific usage demand information, wherein the spare part used for delivery to the transit address is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein the weight of the first spare part and/or Or the volume is smaller than the second spare part, wherein each transit address is used for at least two terminal addresses to be shared;

Acquire all spare part information associated with use in the first spare part and the second spare part, and mark at least two spare parts associated with combined use as combined spare parts;

Determine whether the proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion;

If so, send a suggestion instruction to the center to prioritize the delivery and delivery of such orders under the same conditions, wherein the same conditions include that the order amount of the assembled spare parts before the delivery date of the order is within the same amount difference interval.

As a further solution of the present invention, the combined spare part includes at least one main spare part and all auxiliary spare parts used in cooperation with the main spare part.

As a further scheme of the present invention, the method also includes:

obtaining input on a first time limit for spare parts production, the first time limit representing the total safe estimated time for the spare part to be ready to leave the factory;

obtaining an input of a second time limit for the production of the main spare parts in the combined spare parts, wherein the second time limit represents the first safe estimated time period for which the main and spare parts are about to be shipped from the factory;

Obtaining input of a third time limit for the production of auxiliary spare parts in the combined spare parts, wherein the third time limit represents a second safety estimated time period for the auxiliary spare parts to be finished leaving the factory, wherein the first safety estimated time period and the second safety estimated time period The sum is not greater than the total safe estimated duration.

As a further solution of the present invention, the generation of delivery data for spare parts according to the obtained order information and specific use demand information specifically includes:

acquiring order information in the first area, where the order information includes sub-order information in several second areas, and the first area includes several second areas;

Acquire the specific locations of several second areas, and mark the specific locations of the second areas as the terminal address;

The locations where the distances from all the second areas are within the preset distance are obtained as the transit address, and the transit address is set to at least a storage box for storing auxiliary accessories.

As a further scheme of the present invention, the method also includes:

The coded identification information of the main spare part and the auxiliary spare part is obtained, wherein the coded identification information of the main spare part and the auxiliary spare part at least includes respective feature information and the association and cooperation information between the main spare part and the auxiliary spare part.

As a further scheme of the present invention, the method also includes:

Obtain the amount information in all the order information after the permission is agreed;

Sort the orders according to the size of the amount, and divide the orders before the delivery date into the corresponding equal amount difference interval.

As a further scheme of the present invention, the method also includes:

Obtain the code identification information of the auxiliary spare parts in the sub-areas of all the storage boxes, and when it is judged that the number of auxiliary parts is greater than the number of auxiliary parts required for the actual work corresponding to the main parts, mark that the number is greater than the actual work corresponding to the main parts. The auxiliary parts of the number of auxiliary parts are public auxiliary parts, and the auxiliary parts required for the corresponding actual work are marked as separate auxiliary parts;

For each terminal address, the permission corresponding to obtaining the sub-orders corresponding to the sub-order from the storage box is issued;

When it is recognized that any terminal address sends a demand instruction requesting to obtain a public accessory, send an instruction requesting to obtain an image of an abnormal operation of the individual accessory of the terminal address;

Identify the received image of the individual accessory that is working abnormally. When the identification result indicates that it is the accessory corresponding to the sub-order of the terminal address, the terminal address corresponding to the public accessory with characteristic information obtained from the storage box is issued. authority;

When it is detected that any public accessory is correspondingly taken out by the terminal address, a prompt of the reduction of the public accessory is sent to other associated terminal addresses, wherein the associated terminal address is used to indicate that it has the corresponding taken out public accessory The main components that make up the combined spare part.

As a further solution of the present invention, on the other hand, an intelligent delivery system for spare parts of a new energy power station, a generation module is used to generate delivery data for the spare parts according to the obtained order information and specific usage demand information, wherein the delivery data for the delivery transit address is The spare part is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein the weight and/or volume of the first spare part is smaller than that of the second spare part, and each transit address is shared by at least two terminal addresses;

an acquiring and marking module, configured to acquire all spare part information associated with use in the first spare part and the second spare part, and mark at least two spare parts associated with combined use as combined spare parts;

The judgment module is used to judge whether the quantity proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion;

The suggestion module is used to send a suggestion instruction to the center for prioritizing delivery and delivery of such orders under the same conditions, wherein the equal conditions include that the order amount of the combined spare parts before the delivery date of the order is within the same amount difference range Inside.

An intelligent delivery system and method for spare parts of a new energy power station provided by the embodiments of the present invention generate delivery data for the spare parts according to the obtained order information and specific use demand information, wherein the spare part used for delivery to the transit address is the first spare The second spare part is delivered to the terminal address, wherein the weight and/or volume of the first spare part is smaller than that of the second spare part, and each transit address is shared by at least two terminal addresses. The regional warehouse, the terminal address is applied to the regional warehouse, and the transit address is applied to the smart cabinet, and the spare parts with large weight and/or volume are directly delivered to the terminal address, and the second spare parts can be delivered flexibly; obtain all the related use of the first spare parts and the second spare parts and mark at least two spare parts associated with combined use as combined spare parts, determine whether the proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion, and if so, send it to the center. Suggested instructions for prioritizing delivery of such orders under the same conditions, where the same conditions include that the order amount of the combined spare parts is within the same amount difference range before the delivery date of the order, thereby greatly improving the efficiency of spare parts delivery and providing a backup for the combination Priority is given to the delivery of spare parts, because as long as one of the combined spare parts damages the entire wind farm, the use will be affected by the linkage. At this time, the priority to provide the combined spare parts can provide guarantee for the assembly of the combined spare parts installed in the wind farm and improve the safety factor.

Description of drawings

Fig. 1 is the main flow chart of a method for intelligent delivery of spare parts for a new energy power station.

Fig. 2 is a flow chart of generating delivery data for spare parts according to the obtained order information and specific usage demand information.

FIG. 3 is a flow chart of dividing orders that are all before the delivery date into corresponding equal amount difference intervals.

FIG. 4 is a flow chart related to issuing the terminal address corresponding to the authority to acquire the public accessory with characteristic information from the storage box.

Fig. 5 is a main structural diagram of a spare parts intelligent delivery system of a new energy power station.

Detailed ways

In order to make the objectives, technical solutions and advantages of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention, but not to limit the present invention.

The specific implementation of the present invention will be described in detail below with reference to specific embodiments.

The present invention provides a system and method for intelligent delivery of spare parts for a new energy power station, which solves the technical problems in the background art.

As shown in FIG. 1, it is a main flow chart of a method for intelligently delivering spare parts of a new energy power station according to an embodiment of the present invention. The method for intelligently delivering spare parts of a new energy power station includes:

Step S10: Generate delivery data for the spare parts according to the acquired order information and the specific use demand information, wherein the spare part used for delivery to the transit address is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein the first spare part is The weight and/or volume is smaller than the second spare part, wherein each transit address is used in common for at least two terminal addresses;

Step S11: Acquire all spare parts information associated with use in the first spare part and the second spare part, and mark at least two spare parts associated with combined use as combined spare parts;

Step S12: judging whether the quantity proportion of the combined spare parts in the order information corresponding to the same order is greater than a preset proportion;

Step S13: If yes, send a suggestion instruction to the center to prioritize delivery of such orders under equal conditions, wherein the equal conditions include that the order amount of the assembled spare parts before the delivery date of the order is within the same amount difference interval.

When this embodiment is applied, delivery data is generated for the spare parts according to the obtained order information and specific usage demand information, wherein the spare part used for delivery to the transit address is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein all the spare parts are The weight and/or volume of the first spare part is smaller than that of the second spare part, wherein each transit address is shared by at least two terminal addresses. The smart cabinet directly delivers the spare parts with larger weight and/or volume to the terminal address, and the second spare part can be delivered flexibly; obtains all the spare parts information related to the use of the first spare part and the second spare part, and marks the at least one associated with the combined use. The two spare parts are combined spare parts. Determine whether the proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion. If so, send it to the center to prioritize such orders for delivery under the same conditions. The proposed instruction, wherein the equivalent conditions include that the order amount of the combined spare parts is within the same amount difference range before the delivery date of the order, thereby greatly improving the spare part delivery efficiency and giving priority to the delivery of the combined spare parts, because the combined spare parts only have The use of a damaged wind farm will be affected by linkage. At this time, the combination of spare parts is given priority, which can provide guarantee for the assembly of the combined spare parts installed in the wind farm, improve the safety factor, and ensure that there is a choice under the limited delivery and transportation capacity. , to provide guarantee for the assembly of combined spare parts.

As a preferred embodiment of the present invention, the combined spare part includes at least one main spare part and all auxiliary spare parts used in cooperation with the main spare part.

In the application of this embodiment, there is at least one main spare part, and each main spare part has at least one auxiliary part, and there may be more than one, such as a yaw motor, which may have a main control sensor, a torque sensor, a base, a noise detection unit, etc.

As a preferred embodiment of the present invention, the method further includes:

Step S201 : obtaining an input about a first time limit for spare parts production, where the first time limit represents a total estimated safety time for the spare parts to be finished leaving the factory;

Step S202: obtaining an input of a second time limit for the production of the main spare parts in the combined spare parts, wherein the second time limit represents the first safety estimated time period for which the main and spare parts are about to be shipped from the factory;

Step S203: Obtain the input of the third time limit for the production of auxiliary spare parts in the combined spare parts, wherein the third time limit represents the second safety estimated time period when the auxiliary spare parts are about to be shipped from the factory, wherein the first safety estimated time period and the second safety estimated time period are The sum of the estimated durations is not greater than the total safe estimated duration.

As shown in FIG. 2 , as a preferred embodiment of the present invention, the generation of delivery data for spare parts according to the obtained order information and specific usage demand information specifically includes:

Step S101: Obtain order information of a first area, where the order information includes sub-order information of several second areas, and the first area includes several second areas;

Step S102: Acquire the specific locations of several second areas, and mark the specific locations of the second areas as terminal addresses;

Step S103 : acquiring the locations where the distances from all the second areas within the preset distance are located as the transit address, and the transit address is set to at least a storage box for storing auxiliary accessories.

When this embodiment is applied, for example, the first area is a group, the second area is a regional company under the group, and the transit address is a transit area that is not far from each regional company. It is not far away, so it is convenient for companies in various regions to use them by themselves.

As a preferred embodiment of the present invention, the method further includes:

Step S301 : Acquire the coded identification information of the main spare part and the auxiliary spare part, wherein the coded identification information of the main spare part and the auxiliary spare part at least includes respective feature information and association information between the main spare part and the auxiliary spare part.

In the application of this embodiment, for example, the coded identification information of the main spare part and the auxiliary spare part is 1A00-2A01, where A indicates that there is an associated cooperation between the two, 1 indicates the main part, 2 indicates the auxiliary part, 00 and 01 respectively Indicates the functional model identification code of the main accessory and the auxiliary accessory, such as the yaw motor and the main control sensor (to identify the rotational speed of the yaw motor).

As shown in Figure 3, as a preferred embodiment of the present invention, the method further includes:

Step S401: Acquire the amount information in all the order information after the permission is approved;

Step S402: Sort the orders according to the size of the amount, and divide the orders that are all before the delivery date into corresponding equal-amount difference intervals.

When this embodiment is applied, for example, the order amount is 10, 30, 50, 60, and 80, respectively, and the unit is (ten thousand yuan). Assuming that every 200 thousand yuan is the gradient, 10 falls within the gradient of 0-20. Correspondingly, 30 falls within the 20-40 gradient, and so on, that is to say, it is possible to generate suggestions for almost simultaneous delivery and delivery with a similar amount of money (provided that they are all before the delivery date), and its practical application is reasonable.

As shown in Figure 4, as a preferred embodiment of the present invention, the method further includes:

Step S501: Obtain the coding identification information of the auxiliary spare parts in the sub-areas of all storage boxes, and when it is judged that the number of auxiliary parts is greater than the number of auxiliary parts required for the actual work corresponding to the main parts, mark the number greater than the actual work corresponding to the main parts. The auxiliary parts with the required number of auxiliary parts are public auxiliary parts, and the auxiliary parts required for the corresponding actual work are marked as separate auxiliary parts;

Step S502: for each terminal address, the authority corresponding to obtaining the sub-order corresponding accessory from the storage box is issued;

Step S503: when it is identified that any terminal address sends a demand instruction requesting to acquire a public accessory, an instruction requesting to acquire an image of an abnormal working of the individual accessory of the terminal address is sent;

Step S504: Recognize the received image of the abnormal working of the individual accessory, when the identification result indicates that it is the accessory corresponding to the sub-order of the terminal address, issue the terminal address corresponding to obtaining the public image with characteristic information from the storage box. The authority of the auxiliary accessories can be identified through the trained neural network model, which is the existing technology;

Step S505 : after detecting that any public accessory is correspondingly taken out by the terminal address, send a reminder of the reduction of the public accessory to other associated terminal addresses, wherein the associated terminal address is used to indicate that it has the corresponding taken-out address. The public auxiliary parts constitute the main parts of the combined spare parts. When the total amount of the public auxiliary parts is less than the preset percentage, a notification prompt of supplementing the public auxiliary parts is sent to the headquarters group (equipment) where the first area is located.

When applied in practice, the takeover authority of this part can be obtained by the headquarters group where the first area is located.

It can be understood that, by issuing the permission corresponding to obtaining sub-orders corresponding to the sub-order from the storage box for each terminal address, the (person) of the corresponding terminal address can take out the sub-orders required in the sub-order through this permission. It can be carried out in the form of a corresponding verification identification code, which is not limited here, and when it is identified that any terminal address sends a demand command requesting the acquisition of public accessories, it will send a request to obtain the terminal address. , identify the received image of the individual accessory that is working abnormally, and when the identification result indicates that it is the accessory corresponding to the sub-order of the terminal address, the terminal address is issued corresponding to the public information with characteristic information obtained from the storage box. The permission of the auxiliary accessories, that is to say, the need for the terminal address is really due to the damage of the public auxiliary accessories and the public auxiliary accessories are required, which can form a certain effect of restricting the use, and each required terminal address can be applied for use, and does not need to be used separately. Each terminal address is configured one by one, which has strong practicability. When it is detected that any public accessory is correspondingly taken out by the terminal address, a reminder of the reduction of the public accessory is sent to other associated terminal addresses, wherein the associated terminal The address is used to indicate that it has a main accessory that forms a combined spare part with the correspondingly taken out public accessory, that is to say, the terminal address that does not have a main accessory that forms a combined spare with the correspondingly taken out public accessory will not receive a corresponding prompt, and can The corresponding terminal address forms the effect of paying attention to its own auxiliary accessories in time.

As shown in FIG. 5, as another preferred embodiment of the present invention, on the other hand, an intelligent spare parts delivery system for a new energy power station, the system includes:

The generating module 100 is configured to generate delivery data for spare parts according to the obtained order information and specific use demand information, wherein the spare part used for delivery to the transit address is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein the first spare part is used for delivery to the terminal address. One spare part is smaller in weight and/or volume than the second spare part, wherein each transit address is used for at least two terminal addresses to be shared;

an acquiring and marking module 200, configured to acquire all spare part information associated with use in the first spare part and the second spare part, and mark at least two spare parts associated with combined use as combined spare parts;

The judgment module 300 is used for judging whether the quantity proportion of the combined spare parts in the order information corresponding to the same order is greater than the preset proportion;

The suggestion module 400 is configured to send a suggestion instruction to the center for prioritizing delivery and delivery of such orders under equal conditions, wherein the equal conditions include the difference in the same amount in the order amount of the combined spare parts before the delivery date of the order within the interval.

The above-mentioned embodiment of the present invention provides an intelligent delivery method for spare parts of a new energy power station, and provides an intelligent spare parts delivery system for a new energy power station based on the intelligent delivery method for spare parts of a new energy power station. Specifically, the demand information is used to generate delivery data for spare parts, wherein the spare part used for delivery to the transit address is the first spare part, and the one used for delivery to the terminal address is the second spare part, wherein the weight and/or volume of the first spare part is smaller than that of the second spare part , where each transit address is shared by at least two terminal addresses. Generally speaking, it is to divide the smart cabinet and the regional warehouse, the terminal address is applied to the regional warehouse, and the transfer address is applied to the intelligent cabinet, and the spare parts with large weight and/or volume are directly delivered. Terminal address, the second spare parts can be delivered flexibly; obtain all the spare parts information related to the use of the first spare parts and the second spare parts, and mark at least two spare parts that are related to the combined use as combined spare parts, and determine the corresponding spare parts in the order information. Whether the proportion of the quantity in the same order is greater than the preset proportion, if so, send a suggestion instruction to the center to prioritize the delivery and delivery of such orders under the same conditions, wherein the same conditions include the delivery of the order. The order amount of the combined spare parts before the date is within the same amount difference range, which greatly improves the spare parts delivery efficiency and provides priority for the delivery of the combined spare parts, because as long as one of the combined spare parts damages the entire wind farm, the use will be affected by the linkage. At this time, the combination of spare parts is given priority, which can provide guarantee for the assembly of the combined spare parts installed in the wind farm and improve the safety factor.

In order to be able to load the above-mentioned method and system to run smoothly, in addition to the above-mentioned various modules, the system may also include more or less components than those described above, or combine some components, or different components, for example, may include Input and output devices, network access devices, buses, processors and memories, etc.

The processor may be a central processing unit (Central Processing Unit, CPU), or other general-purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), off-the-shelf programmable gate arrays (Field-ProgrammableGateArray, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, etc. The general-purpose processor can be a microprocessor or the processor can also be any conventional processor, etc. The above-mentioned processor is the control center of the above-mentioned system, and uses various interfaces and lines to connect various parts.

The above-mentioned memory can be used to store computer and system programs and/or modules, and the above-mentioned processor implements the above-mentioned various functions by running or executing the computer programs and/or modules stored in the memory and calling the data stored in the memory. The memory may mainly include a stored program area and a stored data area, wherein the stored program area may store an operating system, an application program required for at least one function (such as an information collection template display function, a product information release function, etc.). The storage data area can store data created according to the use of the berth status display system (such as product information collection templates corresponding to different product types, product information to be released by different product providers, etc.). In addition, the memory may include high-speed random access memory, and may also include non-volatile memory such as hard disk, internal memory, plug-in hard disk, Smart Media Card (SMC), Secure Digital (SD) card, flash memory card (FlashCard), at least one magnetic disk storage device, flash memory device, or other volatile solid state storage device.

It should be understood that although the steps in the flowcharts of the embodiments of the present invention are sequentially displayed according to the arrows, these steps are not necessarily executed in the order indicated by the arrows. Unless explicitly stated herein, the execution of these steps is not strictly limited to the order, and the steps may be executed in other orders. Moreover, at least a part of the steps in each embodiment may include multiple sub-steps or multiple stages. These sub-steps or stages are not necessarily executed and completed at the same time, but may be executed at different times. The order of execution is also not necessarily sequential, but may be performed alternately or alternately with other steps or at least a portion of sub-steps or phases of other steps.

The technical features of the above-described embodiments can be combined arbitrarily. For the sake of brevity, all possible combinations of the technical features in the above-described embodiments are not described. However, as long as there is no contradiction between the combinations of these technical features, All should be regarded as the scope described in this specification.

The above-mentioned embodiments only represent several embodiments of the present invention, and the descriptions thereof are specific and detailed, but should not be construed as limiting the scope of the patent of the present invention. It should be pointed out that for those of ordinary skill in the art, without departing from the concept of the present invention, several modifications and improvements can also be made, which all belong to the protection scope of the present invention. Therefore, the protection scope of the patent of the present invention shall be subject to the appended claims.

The above descriptions are only preferred embodiments of the present invention and are not intended to limit the present invention. Any modifications, equivalent replacements and improvements made within the spirit and principles of the present invention shall be included in the protection of the present invention. within the range.

Claims (8)

1. An intelligent spare part delivery method for a new energy power station is characterized by comprising the following steps:

generating delivery data for the spare parts according to the acquired order information and the specific use requirement information, wherein the spare parts for delivering the transit addresses are first spare parts, the spare parts for delivering the terminal addresses are second spare parts, the weight and/or volume of the first spare parts are smaller than those of the second spare parts, and each transit address is shared by at least two terminal addresses;

acquiring all spare part information with usage association in the first spare part and the second spare part, and marking at least two spare parts with the usage association as combined spare parts;

judging whether the quantity ratio of the combined spare parts in the order information corresponding to the same order is greater than a preset ratio or not;

if yes, a recommendation instruction for giving delivery priority to the orders is sent to the center end under the same condition, wherein the same condition comprises that the order amount of the combined spare parts is within the same amount difference interval before the delivery date of the orders.

2. The intelligent delivery method of spare parts of a new energy power station as claimed in claim 1, wherein the combined spare parts comprise at least one main spare part and all auxiliary spare parts used in cooperation with the main spare part.

3. The intelligent delivery method of spare parts of a new energy power station as claimed in claim 1, characterized in that the method further comprises:

acquiring input of a first time limit related to spare part production, wherein the first time limit represents total safety pre-estimated time for the spare part to finish leaving a factory;

acquiring input of a second time limit of production of the main spare part in the combined spare part, wherein the second time limit represents a first safety pre-estimated time length of the main spare part about to finish leaving a factory;

and acquiring input of a third time limit of the auxiliary spare part production in the combined spare part, wherein the third time limit represents a second safety pre-estimated time length of the auxiliary spare part about to finish delivery, and the sum of the first safety pre-estimated time length and the second safety pre-estimated time length is not more than the total safety pre-estimated time length.

4. The intelligent spare part delivery method for the new energy power station as claimed in claim 2, wherein the generating delivery data for the spare part according to the acquired order information and the specific use requirement information specifically comprises:

acquiring order information of a first area, wherein the order information comprises sub-order information of a plurality of second areas, and the first area comprises the plurality of second areas;

acquiring specific positions of a plurality of second areas, and marking the specific positions of the second areas as terminal addresses;

and acquiring positions of the areas which are within a preset distance from all the second areas as transit addresses, wherein the transit addresses are provided with storage boxes at least used for storing accessories.

5. The intelligent delivery method of spare parts of a new energy power station as claimed in claim 4, characterized in that the method further comprises:

acquiring the coded identification information of the main spare part and the auxiliary spare part, wherein the coded identification information of the main spare part and the auxiliary spare part at least comprises respective characteristic information and associated matching information between the main spare part and the auxiliary spare part.

6. The intelligent delivery method of spare parts of a new energy power station as claimed in claim 1, characterized in that the method further comprises:

obtaining the amount information in all the order information after permission is granted;

the orders are sorted according to the amount, and the orders which are all before the delivery date are divided into corresponding equal amount difference intervals.

7. Intelligent spare part delivery method for a new energy power station according to claim 4 or 5, characterized in that it further comprises:

acquiring coded identification information of auxiliary spare parts in sub-areas of all storage boxes, and marking the auxiliary parts of which the number is larger than that of the auxiliary parts required by actual work corresponding to the main parts as common auxiliary parts and marking the auxiliary parts required by the actual work corresponding to the main parts as independent auxiliary parts when the number of the auxiliary parts is judged to be larger than that of the auxiliary parts required by the actual work corresponding to the main parts;

issuing the authority corresponding to the accessory part corresponding to the sub-order acquired from the storage box for each terminal address;

when any terminal address is identified to send a demand instruction for acquiring public accessories, sending an instruction for acquiring images of the independent accessories of the terminal address with abnormal work;

identifying the received image with the abnormal work of the single accessory, and issuing the authority of acquiring the public accessory with the characteristic information from the storage box corresponding to the terminal address when the identification result represents that the image is the accessory corresponding to the sub-order of the terminal address;

and when any common auxiliary part is detected to be correspondingly taken out by the terminal address, sending a prompt of reducing the common auxiliary part to other associated terminal addresses, wherein the associated terminal addresses are used for representing main parts which have combined spare parts formed by the common auxiliary parts taken out correspondingly.

8. A spare part intelligent delivery system of new energy power station, its characterized in that, the system includes:

the generating module is used for generating delivery data for the spare parts according to the acquired order information and the specific use requirement information, wherein the spare parts used for delivering the transit addresses are first spare parts, the spare parts used for delivering the terminal addresses are second spare parts, the weight and/or the volume of the first spare parts are smaller than those of the second spare parts, and each transit address is shared by at least two terminal addresses;

the acquisition and marking module is used for acquiring all spare part information with associated use in the first spare part and the second spare part and marking at least two spare parts with associated combined use as combined spare parts;

the judging module is used for judging whether the quantity ratio of the combined spare parts in the order information corresponding to the same order is greater than the preset ratio or not;

and if so, sending a recommendation instruction for giving delivery priority to the orders to the central terminal under the same condition, wherein the same condition comprises that the order amount of the combined spare parts is within the same amount difference interval before the delivery date of the orders.

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