RU45060U1 - WIND DIESEL POWER PLANT WITH UNINTERRUPTED POWER SUPPLY - Google Patents

Abstract

The utility model is aimed at simplifying and reducing the cost of the design of a wind-diesel power plant, ensuring uninterrupted power supply to the load, as well as economical fuel consumption. The specified technical result is achieved by the fact that the wind-diesel installation contains a wind-driven installation, the output of which is connected to the first rectifier-charging device, a diesel-electric installation, to the output of which is connected the second rectifier-charger, an inverter, the input of which is connected to the outputs of the first and second rectifier-charging devices , and the output is connected to the load and the control system connected to the input of the diesel-electric installation.

Description

The utility model relates to combined wind-diesel power plants (VDES) and can be used in stand-alone power plants operating independently of a centralized power supply network.

Known VDES, selected as a prototype, containing five wind power installations, the outputs of which are connected rectifier-charging devices, the outputs of which are connected to a battery of batteries, an inverter, the input of which is connected to the outputs of the rectifier-charging devices, and the output is connected to a switching device, a diesel-electric installation , the input of which is connected to the switching device and the load connected to the output of the switching device [D.K. Gagach, V.K. Maltsev. The first wind-diesel power station in Taimyr. Power Engineer, No. 9, 2001, pp. 10-13].

The disadvantage of this device is the complexity and high cost of the electrical circuit of the device due to the use of a battery of batteries, as well as some interruptions in the power supply of the load associated with the loss of time to start the diesel-electric installation and the operation of the switching device. Also in this scheme, the diesel-electric installation operates at a constant speed, and the load schedule and, consequently, the loading of the diesel-electric installation can vary greatly depending on the time of day and other factors, which leads to increased fuel consumption.

The objective of the utility model is to simplify and reduce the cost of the design of a wind-diesel installation, ensure uninterrupted power supply to the load, as well as economical fuel consumption.

The solution to this problem is achieved by the fact that a wind-diesel installation containing a wind-driven installation, the output of which is connected

the first rectifier-charging device, a diesel-electric installation, the output of which is connected to the second rectifier-charging device, an inverter, the input of which is connected to the outputs of the first and second rectifier-charging devices, and the output is connected to the load, according to the utility model is equipped with a control system connected to the input diesel electric installation.

It is the claimed implementation of the scheme that provides the possibility of a more economical and uninterrupted operation of a wind-diesel installation, thereby fulfilling the task of a utility model. This is achieved by the fact that in the proposed scheme, for any excess of power consumed by the load over the power generated by the wind power installation, the control system generates a control signal and increases the power of the diesel-electric installation. When reducing the power consumed by the load, the diesel-electric installation reduces the speed, and if the wind-electric installation generates sufficient power to provide power to the load, the diesel-electric installation operates in idle mode at minimum speed. This makes it possible to instantly compensate for any changes in the magnitude of the load.

The drawing shows a structural diagram of a wind-diesel power plant. The device comprises a wind power installation 1 (wind turbine), the output of which is connected to the first rectifier-charger 2 (VZU 1), a diesel-electric installation 3 (DEU), to the output of which is connected the second rectifier-charger 4 (VZU 2), inverter 5, input which is connected to the outputs of the first rectifier-charging device 2 (VZU 1) and the second rectifier-charging device 4 (VZU 2), and the output is connected to the load 6. The control system 7 is connected to the input of the diesel-electric installation 3 (DEU).

In this scheme, an autonomous wind power station can be used as a wind power plant 1 (wind turbine), and the first rectifier-charging device 2 (wind turbine 1) can be used

three-phase bridge rectifier with voltage regulator. In the circuit, a diesel-electric installation 3 (DEU) of equal power with a wind-electric installation 1 (wind turbine) can be used, and a three-phase bridge rectifier can also be used as the second rectifier-charging device 4 (ВЗУ 2). In this scheme, a standalone inverter 5 can be used, and as a control system 7, a microcontroller fuel injection control system in diesel electric installation 3 (DEU) can be used. As the load 6 can be used with any electrical appliances.

The device operates as follows. Under the influence of the wind, wind power installation 1 (wind turbine) generates electricity that is supplied to the first rectifier-charging device 2 (VZU1), direct current from the output of the first rectifier-charging device 2 (VZU 1) is supplied to the inverter 5, which converts the direct current into electricity with standard parameters for supplying load 6. When the wind flow decreases or load 6 increases, control system 7 generates a control signal and increases the speed of diesel-electric installation 3 (DEU), which About this Idled. The energy generated by the diesel-electric installation 3 (DEU) is supplied to the second rectifier-charging device 4 (VZU 2), and the direct current from the output of the second rectifier-charging device 4 (VZU 2) is supplied to the inverter 5, which converts the direct current into electricity with standard parameters for additional load supply 6.

Claims (1)

A wind-diesel power plant containing a wind-driven installation, the output of which is connected to the first rectifier-charger, a diesel-electric installation, to the output of which is connected a second rectifier-charger, an inverter, the input of which is connected to the outputs of the first and second rectifier-charging devices, and the output is connected to the load , characterized in that it additionally introduced a control system included in the input of the diesel-electric installation.