From Spreadsheets to Multiphysics Applications, ABB Continues to Power Up the Transformer Industry
公司规模
1,000+
地区
- Europe
国家
- Sweden
- Switzerland
产品
- COMSOL Multiphysics
- Application Builder
- COMSOL Server
技术栈
- Finite Element Analysis
- Java
- Electromagnetic Simulation
- Acoustic Simulation
实施规模
- Enterprise-wide Deployment
影响指标
- Customer Satisfaction
- Innovation Output
- Productivity Improvements
技术
- 分析与建模 - 预测分析
- 分析与建模 - 实时分析
- 应用基础设施与中间件 - 数据可视化
适用行业
- 电网
- 公用事业
适用功能
- 产品研发
- 质量保证
用例
- 机器状态监测
- 预测性维护
- 过程控制与优化
服务
- 软件设计与工程服务
- 系统集成
- 培训
关于客户
ABB is one of the biggest manufacturers of transformers used around the world, headquartered in Zürich, Switzerland. The company is renowned for its expertise in power and automation technologies, providing solutions for a wide range of industries including utilities, industry, transport, and infrastructure. ABB’s transformers are integral to the electrical grid, which powers buildings like homes, businesses, and schools. The company’s transformers are used to increase and decrease voltage levels in power lines that carry alternating current, ensuring efficient and safe power transmission over long distances. ABB’s commitment to innovation and quality has led them to use advanced numerical analyses and computational applications to predict and minimize noise levels in their transformers, ensuring compliance with safety regulations and enhancing customer satisfaction.
挑战
Companies developing new and improved power transformer equipment incur costs for prototyping and testing as they work to reduce transformer hum. At ABB, a team of engineers develops multiphysics simulations and custom-built applications to offer insight into their designs. Transformer noise often comes from several sources, such as vibrations in the transformer core or auxiliary fans and pumps used in the cooling system. Each of these sources needs to be addressed differently to reduce noise. ABB’s transformers comprise a metal core with coils of wire wound around different sections, an enclosure or tank to protect these components, and an insulating oil inside the tank. Passing alternating current through the windings of one coil creates a magnetic flux that induces current in an adjacent coil. The voltage adjustment is achieved through different numbers of coil turns. Because the core is made of steel, a magnetostrictive material, these magnetic fluxes — which alternate direction — cause mechanical strains. This generates vibrations from the quick growing and shrinking of the metal. These vibrations travel to the tank walls through the oil and the clamping points that hold the inner core in place, creating an audible hum known as core noise. In addition to the core noise, the alternating current in the coil produces Lorentz forces in the individual windings, causing vibrations known as load noise that add to the mechanical energy transferred to the tank.
解决方案
The ABB Corporate Research Center (ABB CRC) in Västerås, Sweden, developed a series of simulations and computational apps using COMSOL Multiphysics® simulation software and its Application Builder. These tools calculate magnetic flux generated in the transformer core and windings, Lorentz forces in the windings, mechanical displacements caused by magnetostrictive strains, and the resulting pressure levels of acoustic waves propagating through the tank. The team created an electromagnetic model to predict the magnetic fields induced by the alternating current and the magnetostrictive strains in the steel. They then calculated the resonance for different frequencies using a modal analysis, predicting the sound waves moving through the oil and calculating the resulting vibrations of the tank. This allowed them to adjust the geometry and setup of the core, windings, and tank to minimize noise. The CRC team also developed custom applications using the Application Builder, which can be easily customized to suit the needs of different departments within ABB. These applications simplify testing and verification for designers and R&D engineers, allowing them to access finite element analysis through a user interface without needing to learn finite element theory. The applications include both the physics model developed in the COMSOL® software and custom methods written in Java® code, programmed within the Application Builder.
运营影响
数量效益
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