SU1178906A1 - Regulation system of extraction turbine plant - Google Patents

Abstract

A REGULATION SYSTEM FOR THERMAL VALVE PAROTTURBINE INSTALLATION, containing a power regulator, the output of which is connected to the servo-motor of high-pressure control valves and to the inlet of the vapor pressure regulator in the selection to the mains heater, and a bypass valve installed on the bypass network heater and equipped with a driving mechanism and equipped with a driving mechanism. with the output of the pressure regulator, characterized in that; that, in order to increase the capacity of the installation in case of emergency power shortages in the power system, the system is equipped with a bypass valve closing unit and an emergency power shortage signal sensor connected to the input of the closing unit, and the drive mechanism additionally (L connected to the output of the bypass valve closing unit. 00 with about O5

Description

The invention relates to a power system and can be used "to regulate heating plants with large thermal loads. 5

The purpose of the invention is to increase the injectivity of the installation in case of emergency power shortages in the power system.

The drawing shows a diagram of a control system for a heating 10 steam turbine installation.

The system comprises a turbine high pressure cylinder 1, a turbine low pressure cylinder 2, a condenser 3, a power regulator 4 connected to a servomotor 5 of high pressure control valves 6, a steam pressure regulator 7 in the selection connected to the actuator 8 of the bypass valve 9 on bypass lines 20 and network heater 10, bypass valve closing block 11, connected to the emergency power shortage signal sensor 12 in the power system, turbine power task 25 change unit 13, connected to the sensor output 12. Regulating diaphragm 14 of the cylinder 2 low pressure. turbine line is closed.

The regulatory system operates _3Q as follows.

If it is necessary to reduce the electric power and maintain a constant thermal load of the turbine, the power controller 4 through the servomotor 5 sends a signal to close ³⁵ high-pressure valves 6. Simultaneously, power from the controller 4 receives a signal at the input of the pressure regulator 7, a pair in the selection, koto- _n zijfu acts on the drive mechanism 8 of the bypass valve 9 in the direction of its opening. The latter leads to an increase in steam pressure in the network heater 10, while the triggered heat drop of the high-pressure cylinder 1 and, accordingly, the turbine power are reduced.

If you want to increase the heat load with constant electrical power, then using the regulator 7, the steam pressure in the selection act on the actuator 8 of the bypass valve 9, and the latter opens. The consumption of network water through the heater 10 decreases, the pressure in the selection increases and the triggered heat drop of the high-pressure cylinder 1 decreases. The power controller 4, acting on the deviation of the actual power from the set value, opens the high pressure valves 6, the steam consumption increases, and with it the steam pressure in the selection and, accordingly, the thermal load of the turbine also increase. At the same time, the constancy of electric power is maintained by reducing heat loss on the high-pressure cylinder.

In both cases, the control process ends with the corresponding opening of the bypass valve and an increase in pressure in the heating system. This mode of operation of the turbine has a certain reserve for quick power gain. In the event of an emergency power shortage in the power system and the need for a quick set of power in cogeneration steam turbine plants, a signal is sent from the sensor 12 to the input of the bypass valve closing unit 11, as a result of which the bypass valve 9 closes at maximum speed. This increases the flow of network water through the heater 10 and the pressure in it decreases. The increase in heat loss on the high-pressure cylinder 1 leads to an increase in the turbine power and, accordingly, the electric power of the generator. To maintain a constant flow rate of steam through the turbine to the power regulator 4 from the block 13 changes the task of power controlled by the sensor 12, a signal is applied to increase the power of the turbine. The magnitude of this signal should be proportional to the additional power of the turbine obtained by reducing the pressure in the selection. The latter is necessary to bring the set power into correspondence with its actual value.

vniipi

Order 5626/29

Circulation 497

Subscription

Branch of the Chamber of Commerce and Industry '’Patent”, Uzhgorod, Project 4,

Claims (1)

REGULATORY SYSTEM FOR HEATING FITTING STEAM TURBINE INSTALLATION, comprising a power regulator, the output of which is connected to a high-pressure control valve servomotor and to the input of the steam pressure regulator in the selection to the network heater, and a bypass valve installed on the by-pass line of the heater and equipped with a drive mechanism, input which is connected to the output of the pressure regulator, characterized in that: that, in order to increase the injectivity of the installation in case of emergency power shortages in the power system, closing the bypass valve on the unit and emergency power shortage sensor signal connected to the input of the closing unit and the input § actuator is further coupled to the output of closing the bypass valve. SU „p 1178906 1 1178906 2