3.1

Electric topology data

As the basis of distribution network planning, the integrity and accuracy of distribution network topology basic data and problem base directly affect the preparation of power network problem base. Incorrect basic data cannot truly reflect the operation of the power grid, which will affect the formulation of the planning scheme. On the one hand, it may cause waste of investment, on the other hand, it may lead to the failure to effectively solve the power grid problems.

With the development of energy Internet and information technology and the proposition of the concept of ubiquitous Internet of Things, the data of power allocation and utilization in the new environment is easier to obtain, but the data quality needs to be improved. In the intelligent distribution network, data mainly comes from hundreds of millions of smart meters, smart appliances and distributed storage devices. In addition, different power companies or organizations adopt different definitions, storage and management standards, and the multi-source data obtained is usually heterogeneous and independent. The figure below shows the data integration scenario in the intelligent distribution network, involving the data acquisition layer, information system layer and business management layer. The integration of measurement data management and other business management systems gradually realizes data sharing among automatic measurement systems, marketing management systems and production scheduling systems.

As is shown in figure.2, the integration of multi-source and heterogeneous data of distribution network in the new environment brings many challenges to data quality management, which makes information systems prone to data quality problems, mainly in the following four aspects.

Figure 2.

Electric topology data flow process

There are many reasons for data quality problems. Data quality problems are mainly reflected in four aspects, namely, single data source model layer, single data source instance layer, multiple data source model layer and multiple data source instance layer.

3.2

Evaluation method of electric topology data quality

The evaluation of electric topology data quality is a comprehensive and systematic project. The evaluation process of data quality needs to comprehensively consider the importance, regional, difference, real-time and other influencing factors. Through the analysis of the influencing factors of data quality, the relevant theories and methods of data quality evaluation index system are studied. In terms of the importance of data, due to the different security and reliability levels of data and different users, the requirements for the accuracy and timeliness of data are also different.

In order to make the evaluation process of topology data quality more clear and transparent, this paper designs the corresponding evaluation process based on the evaluation dimensions and evaluation model of distribution network topology data quality.

According to the designed intelligent distribution network data quality evaluation process, the specific evaluation process steps are as follows:

According to the data quality score obtained, the level of the data quality “I, II, III, VI, V” is evaluated, If the quality score is A ∈ (0, a], the data quality level of the evaluation data object is evaluated as “V”; if A ∈ (a, b], the data quality level of the evaluation data object is evaluated as “VI”; if A∈ (b, c], the data quality level of the evaluation data object is evaluated as “III”; if A ∈ (c, d], the data quality level of the evaluation data object is evaluated as “II”; if A ∈ (d, e], the data quality level of the evaluation data object is evaluated as “I”, and the specific range can be set according to their respective requirements.

4.1

Electric topology data improvement bases on basic data rules

Topology verification at the data level starts with structural processing of data. Many data models and algorithms are built on structured data. To better integrate multi-source heterogeneous data with other data sets, structural processing is an essential process. Data structure processing should first analyze the original data, extract the required information, and then further transform it into structured data. Many unstructured data and Web data exist in the form of text. Information extraction technology is needed to identify entities, attributes, relationships and other information in the text. There are also many data models that are more structured, such as the JSO format. This type of data is more flexible than relational data and requires some technical processing in the process of structural transformation. The main output form of structured processing is two-dimensional table or graph data, which requires users to determine the rules used in the data conversion process.

As is shown in figure 4, according to the association of electric topology and the need of topology editing, the electric topology is divided and merged, and the topology within the specified range is divided into two-dimensional grids according to the two-dimensional boundary division requirements of the grid.

Figure 4.

Electric topology data improvement bases on basic data rules

According to the results of electric research, the large-scale electric topology network is divided into many small electric topology sub zones, and the analysis, monitoring and optimization of each zone can not only improve the stability of the entire electric system, but also optimize the control effect and reduce the operation cost. The division of reactive electric and voltage is of great significance to the security and stability of electric system. However, the traditional division of reactive electric area is mainly based on geographical units, with reference to operating experience, lacking of systematic theoretical basis. The characteristics of reactive electric are used to partition and identify the electric grid. This method accords with the operation characteristics of complex electric grid.

The division of the electric topology area must comply with the following three basic principles. The first is that each zone should contain at least one generator node to ensure the supply of reactive electric and the incontestability and stability of the voltage within the zone. The second is that the reasonable electric grid topology division requires the balance of supply and demand within the electric grid partitions. The partitions are connected by connecting lines, and the adjacent electric grids are standby for each other. The third is the strong coupling within each zone of the electric grid, and the weak coupling between zones, that is, the voltage change of this zone has little impact on the voltage change of adjacent zones.

4.2

Electric topology data improvement bases on electric business rules

At the electric topology business level, the causes of the problems at the business level are sorted out. According to the grid business and business rules, the problems at the business level mainly include equipment connectivity, line and single line diagram consistency, distribution transformer and substation area diagram consistency, “figure number” consistency, etc. Aiming at the above problems, an automatic business verification rule system is built to check the above several topology data business level problems.

Figure 5.

Electric topology data improvement bases on electric business rules

As is shown in figure3, the rule base for automatic improvement of electric topology data quality at the business level is built as follows:

Above all, at the business level, research and establish evaluation indicators from the logic, relevance, integration and other dimensions of the business. On this basis, research and build a multi-level, multi-directional and multi-dimensional distribution network topology data quality evaluation system to help understand the true level of distribution network topology data quality and support the deepening application and decision-making of distribution network.