A method for manufacturing an integrated power-generation steam turbine unit.

Assembling the steam turbine unit and the power-generation steam turbine unit separately would result in a larger overall assembly volume, a greater number of parts, and higher assembly requirements. Moreover, it would necessitate connecting the rotors via couplings for alignment; even slight deviations could lead to vibrations, preventing the rotors from reaching high speeds and thereby reducing operational efficiency. To address these challenges, technicians have developed an integrated power-generation steam turbine unit. To achieve the aforementioned objectives, this power-generation steam turbine unit employs the following technical solution...

Application of Steam Turbine Generating Units in Power Plants

The turbine control, monitoring, and protection system of a power plant is the system that governs the operation of steam turbine-generator units. Its structure is divided into two main parts: an electrically controlled servo system and a hydraulic system. The hydraulic system itself comprises an oil supply unit and hydraulic actuators. Since the DEH system controls the steam admission to the turbine-generator unit by adjusting the hydraulic actuators, the adjustment process is highly precise. Most of the shortcomings and accidents in the industry stem from substandard oil quality, which can lead to internal leakage in electro-hydraulic converters and jamming of hydraulic actuators.

An Improved Steam Turbine Unit Structure

The steam turbine is a critical piece of equipment in thermal power generation, and its normal operation directly affects the overall operational status of the entire steam turbine unit. When the power-generation steam turbine unit is in a hot state, the turbine’s main shaft expands and shifts axially and radially due to heating, causing the coupling connected to the drive shaft of the main oil pump to twist and deform, eventually leading to damage and severely impacting the turbine’s normal operation. Currently, various connection methods between the turbine’s main shaft and the drive shaft have helped address the issue of short service life in conventional coupling devices.

A steam turbine generator set based on a tower-type solar thermal power plant.

There are many existing methods for improving the thermal efficiency of steam turbine units, including reheat and supplementary combustion—energy-saving and consumption-reducing measures that can significantly enhance the power-generation efficiency of steam turbine units. However, further improvements in unit efficiency still face technical bottlenecks. In light of this, technical experts in this field are dedicated to developing a new type of steam turbine unit specifically designed for tower-type solar thermal power generation, which could once again boost the unit’s efficiency beyond current levels.

What is a steam turbine, and what are its components?

A steam turbine is a device that converts thermal energy from steam into mechanical work. Steam flows through pipelines, transferring heat to the boiler, where it is heated to high temperature and high pressure, after which it is ejected through nozzles. The main components of a steam turbine include the turbine rotor itself, the turbine condensation system, auxiliary equipment, the shaft sealing system, the ventilation system, the electrical system, and electrical protection devices. Among these, the turbine rotor itself is the critical component, while all other components serve primarily to support and ensure the proper functioning of the rotor.

Application of Steam Turbine Generating Units in Power Plants

The steam turbine generator set is a medium- to large-scale power-generation device used in power plants. It primarily supplies main steam and reheat steam within the power plant and also delivers electrical power to the generator. The generator set consists of two major components: the steam turbine and the generator. During operation, both components generate large amounts of steam. After undergoing heat exchange, this steam becomes superheated steam. As the steam's pressure and temperature rise, it then enters the steam turbine to generate electricity.