CN-122022610-A - Energy storage system optimization arrangement construction method and system

Abstract

The application relates to the technical field of energy storage systems, in particular to an optimized arrangement construction method and system of an energy storage system. The method comprises the steps of obtaining structural parameters to be constructed and characteristic data packages of an energy storage system, generating a plurality of construction subtasks according to the structural parameters to be constructed, setting a primary processing strategy according to a preset construction processing model and the characteristic data packages, establishing the construction parameters of the set energy storage system according to the primary processing strategy and all the construction subtasks, generating a construction processing model by integrating historical construction data of various energy storage systems, quickly adapting the construction strategy according to the characteristic data of the current energy storage system, dynamically adjusting the construction parameters in time through periodical simulation verification, and guaranteeing the overall construction quality. The energy storage system is disassembled to be constructed, a plurality of construction subtasks are set, all the construction subtasks are screened and aggregated according to a preset construction period, multi-task parallel construction is realized, and construction efficiency is improved.

Inventors

• LIU HONGXI
• YI HONGBO
• ZHANG LIANG
• LIU YIZE
• Peng Ganyu
• YE JING
• LIU YUXIANG
• LIU YAXIN

Assignees

• 华能秦煤瑞金发电有限责任公司

Dates

Publication Date

20260512

Application Date

20251231

Claims (10)

1. 1. An optimized layout construction method of an energy storage system is characterized by comprising the following steps: Acquiring a to-be-constructed structural parameter and a characteristic data packet of an energy storage system; generating a plurality of construction subtasks according to the structural parameters to be constructed, and setting a primary treatment strategy according to a preset construction treatment model and a characteristic data packet; and establishing and setting construction parameters of the energy storage system according to the primary treatment strategy and all construction subtasks.
2. 2. The method for optimizing an energy storage system according to claim 1, wherein the preset construction process model comprises: Establishing a history construction library; Setting a plurality of energy storage structures according to a historical construction library, and establishing an energy storage structure array A; a= (a 1, a2.. ai...an), wherein, the ai is the ith energy storage structure, n is the number of the energy storage structures; sequentially setting ai as a target energy storage structure according to the energy storage structure array A; setting a monitoring sub-strategy of a target energy storage structure; the monitoring sub-strategy comprises a plurality of verification time nodes and a simulation verification model; Setting monitoring sub-strategies of each energy storage structure in sequence; and constructing a construction processing model according to all the monitoring sub-strategies.
3. 3. The method for optimizing an energy storage system according to claim 2, wherein the setting of the primary treatment strategy includes: generating similar values of the energy storage system and each energy storage structure according to the characteristic data packet; setting a monitoring sub-strategy of the energy storage structure corresponding to the maximum value in all the similar values as a primary monitoring strategy; Setting a plurality of construction periods according to a primary monitoring strategy; setting a simulation monitoring model according to the feature data packet and the simulation verification model in the primary monitoring strategy And setting a primary treatment strategy according to all construction subcycles and the simulation monitoring model.
4. 4. The method for optimizing an energy storage system according to claim 3, wherein the setting of the construction parameters of the energy storage system comprises: A construction cycle series T, t= (T1, t2.. ti...tm.), wherein, ti is the ith construction period set based on the time series; m is the number of construction cycles; Sequentially setting ti as a target construction period according to the construction period sequence T; generating a first-level aggregation instruction; Generating an associated task set of the target construction period according to the first-level aggregation instruction; Generating an associated task set of each construction sub-period in sequence; And setting construction parameters of the energy storage system according to all the associated task sets.
5. 5. The method for optimizing an energy storage system according to claim 4, wherein the setting the construction parameters of the energy storage system comprises: Sequentially setting ti as a period to be executed according to the construction period sequence T; Acquiring an associated task set of a period to be executed; The associated task set comprises a plurality of associated subtasks; generating a plurality of construction sub-strategies of a period to be executed according to a preset construction optimization model and all associated sub-tasks; a construction sub-policy number sequence W, w= (W1, w2... wi...wr), wherein, wi is the ith construction sub-strategy; r is the number of construction sub-strategies; Sequentially setting wi as a target construction strategy according to the construction sub-strategy number row W; Generating a construction evaluation value f of a target construction strategy; f=[ βi*si]; wherein, theta 1 is the number of construction evaluation indexes, beta i is the influence factor of the ith construction evaluation index, si is the reference value of the ith construction evaluation index in the target construction strategy; sequentially generating construction evaluation values of all construction sub-strategies; selecting a construction sub-strategy corresponding to the maximum value in all construction evaluation values as a primary construction strategy of a period to be executed; Setting construction parameters of a period to be executed according to a primary construction strategy; and setting construction parameters of each construction period in sequence.
6. 6. The method for optimizing an energy storage system according to claim 5, wherein the setting of the construction parameters of the cycle to be performed comprises: Setting a plurality of progress feedback nodes according to a primary construction strategy; acquiring a monitoring data packet of a feedback node of the current progress; generating a progress deviation value of the current progress feedback node according to the monitoring data packet; presetting a progress deviation value threshold; if the progress deviation value is larger than a preset progress deviation value threshold value; And the current progress feedback time node generates a first-level correction instruction.
7. 7. The method for optimizing the layout of an energy storage system according to claim 6, wherein the setting of the construction parameters of the energy storage system further comprises: Setting the end time node of each construction period as a verification time node; acquiring a construction record packet of a current verification time node; generating an expected running state of the energy storage structure according to the simulation monitoring model and the construction record packet; Setting a construction subtask which is not executed by the current verification time node as a subtask to be verified; Generating interference values of all subtasks to be verified; Presetting an interference value threshold D1; if D1< di (i=1, 2..n1), generating a secondary correction instruction of the i-th subtask to be verified; wherein n1 is the number of subtasks to be verified, and di is the ith subtask to be verified.
8. 8. An energy storage system optimizing arrangement construction system, adopting the energy storage system optimizing arrangement construction method as set forth in any one of the preceding claims 1 to 7, characterized by comprising: The data sensing unit is used for acquiring the structural parameters to be constructed and the characteristic data packet of the energy storage system; A central control unit comprising: The first processing module is used for generating a plurality of construction subtasks according to the structural parameters to be constructed; the second processing module is used for setting a primary processing strategy according to a preset construction processing model and the characteristic data packet; The third processing module is used for establishing and setting construction parameters of the energy storage system according to the primary processing strategy and all construction subtasks; wherein, preset construction treatment model includes: Establishing a history construction library; Setting a plurality of energy storage structures according to a historical construction library, and establishing an energy storage structure array A; a= (a 1, a2.. ai...an), wherein, the ai is the ith energy storage structure, n is the number of the energy storage structures; sequentially setting ai as a target energy storage structure according to the energy storage structure array A; setting a monitoring sub-strategy of a target energy storage structure; the monitoring sub-strategy comprises a plurality of verification time nodes and a simulation verification model; Setting monitoring sub-strategies of each energy storage structure in sequence; and constructing a construction processing model according to all the monitoring sub-strategies.
9. 9. The energy storage system of claim 8, wherein the second processing module is further configured to: generating similar values of the energy storage system and each energy storage structure according to the characteristic data packet; setting a monitoring sub-strategy of the energy storage structure corresponding to the maximum value in all the similar values as a primary monitoring strategy; Setting a plurality of construction periods according to a primary monitoring strategy; setting a simulation monitoring model according to the feature data packet and the simulation verification model in the primary monitoring strategy And setting a primary treatment strategy according to all construction subcycles and the simulation monitoring model.
10. 10. The energy storage system of claim 9, wherein the third processing module is further configured to: Sequentially setting ti as a period to be executed according to the construction period sequence T; Acquiring an associated task set of a period to be executed; The associated task set comprises a plurality of associated subtasks; generating a plurality of construction sub-strategies of a period to be executed according to a preset construction optimization model and all associated sub-tasks; a construction sub-policy number sequence W, w= (W1, w2... wi...wr), wherein, wi is the ith construction sub-strategy; r is the number of construction sub-strategies; Sequentially setting wi as a target construction strategy according to the construction sub-strategy number row W; Generating a construction evaluation value f of a target construction strategy; f=[ βi*si]; wherein, theta 1 is the number of construction evaluation indexes, beta i is the influence factor of the ith construction evaluation index, si is the reference value of the ith construction evaluation index in the target construction strategy; sequentially generating construction evaluation values of all construction sub-strategies; selecting a construction sub-strategy corresponding to the maximum value in all construction evaluation values as a primary construction strategy of a period to be executed; Setting construction parameters of a period to be executed according to a primary construction strategy; and setting construction parameters of each construction period in sequence.

Description

Energy storage system optimization arrangement construction method and system Technical Field The application relates to the technical field of energy storage systems, in particular to an optimized arrangement construction method and system of an energy storage system. Background Along with the development of the energy storage system to the large-scale and high-density direction, the construction method of the traditional container type energy storage facility is difficult to meet the requirements of efficient construction and fine management. In the prior art, a modularized prefabricated cabin body is usually adopted, but a plurality of systems such as a battery rack, a thermal management air duct, a cable bridge, a fire-fighting pipe network and the like in the cabin are arranged in a staggered manner in a limited space, and installation conflict is often caused by insufficient process coordination in construction. For example, after installation of the battery clusters, the later-stage pipe-laying paths are often blocked, and the earlier-fixed main bridge may affect the optimal layout of the large ventilation pipes, resulting in rework modification and construction delays. The current construction flow depends on two-dimensional drawings and experience judgment, and is lack of previewing and dynamic optimization of structural interference in a three-dimensional space. Although part of schemes introduce BIM technology to perform static collision detection, the design model cannot be related to the real-time construction progress depth, the working procedures cannot be dynamically adjusted according to the site conditions, the traditional method lacks systematic modeling of a construction logic chain, and the influence of a certain working procedure change on the overall progress is difficult to quantitatively evaluate. When equipment arrival is delayed or foundation construction is delayed, projects often wait passively, and subsequent operation sequences which can be developed in parallel cannot be intelligently recombined, so that resource idling and construction period loss are caused. Disclosure of Invention The application aims to solve the technical problems, provides an optimized arrangement construction method and system of an energy storage system, and aims to improve the construction efficiency and the construction quality of the energy storage system. In some embodiments of the application, the construction processing model is generated by integrating the historical construction data of various energy storage systems, the construction strategy can be quickly adapted according to the characteristic data of the current energy storage system, and the construction parameters can be dynamically adjusted in time through periodical simulation verification, so that the overall construction quality is ensured. In some embodiments of the application, a plurality of construction subtasks are set by disassembling a structure to be constructed of the energy storage system, all the construction subtasks are screened and aggregated according to a preset construction period, the multi-task parallel construction is realized, and real-time construction parameters are corrected in time through periodical progress monitoring, so that the construction efficiency is improved. In some embodiments of the present application, an optimized arrangement construction method of an energy storage system is provided, including: Acquiring a to-be-constructed structural parameter and a characteristic data packet of an energy storage system; generating a plurality of construction subtasks according to the structural parameters to be constructed, and setting a primary treatment strategy according to a preset construction treatment model and a characteristic data packet; and establishing and setting construction parameters of the energy storage system according to the primary treatment strategy and all construction subtasks. In some embodiments of the present application, the preset construction process model includes: Establishing a history construction library; Setting a plurality of energy storage structures according to a historical construction library, and establishing an energy storage structure array A; a= (a 1, a2.. ai...an), wherein, the ai is the ith energy storage structure, n is the number of the energy storage structures; sequentially setting ai as a target energy storage structure according to the energy storage structure array A; setting a monitoring sub-strategy of a target energy storage structure; the monitoring sub-strategy comprises a plurality of verification time nodes and a simulation verification model; Setting monitoring sub-strategies of each energy storage structure in sequence; and constructing a construction processing model according to all the monitoring sub-strategies. In some embodiments of the application, the setting a primary processing policy includes: generating similar values of the energy