CS213744B1 - Connection of the regulation loop of the electronic regulation of turbines for the saturated vapour - Google Patents

Description

The invention relates to the connection of an electronic turbine control loop to saturated steam, which prevents the turbine set from being disconnected from the mains in the event of the main reactor circulation pumps being switched off.

The present solutions do not use a safeguard of saturated steam turbines against a pressure drop in the main steam collector of the secondary circuit of a nuclear power plant, caused for example by a failure of the main circulation pumps. It is known that, for example, if four main circulation pumps are used, the nuclear reactor power will decrease by about 25% in the event of a failure of one of them and even by 50% if the two main circulation pumps fail.

In the prior art, two types of steam turbine control for saturated steam are used, depending on its incorporation into the control loop, especially when two or more steam turbines are connected to one nuclear reactor. In these cases, either the turbine towers are connected to the power control loop, or some of them are connected to the inlet steam pressure control loop. When all turbines are connected to the power control loop, the turbine shuts down when the main inlet pump is switched off, for example, when the inlet steam pressure drops enormously. If one of the turbines is connected to the inlet steam pressure control loop, if the pressure drops considerably, for example by switching off the two ee of the four main circulation pumps, the tuxbin will also be shut down. Only in the case of smaller pressure failures, the turbine connected to the pressure control loop is able to handle the

but at the cost of a significant change in performance.

The described disadvantages are substantially limited by the connection of the electronic turbine control loop to the saturated spring, consisting of a pressure corrector, at least one switch and one switch, a logic element and a pressure analyzer. The essence of this connection is that the pressure analyzer output is connected to the input of a pressure corrector whose output is connected to a switch whose contact is connected to the first summation member of the power control burner, while the switch is connected to the first output of the logic element whose inputs are connected to the funkoe evaluation circuit of the nuclear reactor circulation pumps, and the second output of this logic element is connected to a power control loop switch.

An essential advantage of the control loop connection according to the invention is to ensure that the pressure level of the inlet steam is above the shut-off limit, so that the turbines are not shut down and thus energy losses and turbine life are not reduced.

One example of a practical embodiment of an electronic turbine control loop connection to saturated steam is shown in the accompanying drawing, which shows a block diagram of this circuitry and its incorporation into a turbine power control circuit in a no-go operation.

As can be seen from this drawing, the circuit according to the invention consists of a pressure corrector 6 with an inlet 10 and an output 60, a switch 2 with a contact 13, a switch 6 with a first contact 14 and a second contact 15. and with a second output 41 and with inputs 42 from the pressure analyzer s with the output 50 and the first summation member..

This wiring is connected to the turbine power control circuit 100 by closing contact 13 of switch 6 and thereby connecting it to summation member 6 and to turbine power setpoint line 60: to the main steam collector 70, the circuit according to the invention is connected via output 50 of pressure analyzer.

In the logic element 6, the status signals Rq of the main circulation pumps not processed in the drawing are processed. In trouble-free operation, the pressure corrector outlet 11 is disconnected from the switch contact 13. Since the signal pressure variations Ρθ steam inlet is below the activation value, the operation of the turbine 100 controlled by the signal Rg specified performance that vyoházl of the supplying member 61 through a first adding member to a second summation £ 62. In it encounters ee N signal _with actual performance, whereupon as N _Q signal power odohylky controller 66 proceeds to power and via a first switch contact 14 to £ ovládaoího regulatory member 67 £ valves turbine 100. signal P _Q variation of steam pressure in main steam collector 70 is built up in the pressure analyzer £ difference signal P _{from the} specified steam pressure and the actual steam pressure Pg signal. The inlet vapor pressure variation signal vystup outputs from the pressure analyzer £ through output 50 and enters the pressure corrector jeho through its input 0 0. In the pressure corrector 8, the value of the pressure deflection signal Ρθ is processed to a suitable power change value AP, which is applied via the switch contact £ to the specified power circuit H _{from the} turbine power control loop 100 when the main circulation pumps have been disconnected. Closing of switch 2 in the event of a failure of the main circulation pump will be performed by the logic member 6 via its output 40. If the main circulation pump fails and thus the actual steam pressure in the main steam collector 61 falls, the logiocouple 6 emits oovel from the first output. switch 1 to switch to contact 1 £. Thereby the pressure corrector 6 is connected to the first 3

AND

213 744 to the summation member 6 and to the power line 60. The pressure corrector 6 is limited to reducing the specified power Ng of the turbine 100 in case the actual steam pressure in the main steam collector 70 falls below the nominal steam pressure. The effect of the pressure corrector 6 is such that if this actual vapor pressure drops to the shutdown limit, the pressure corrector 6 completely relieves the turbine 100 so that it is not shut down.

The second member 41, by its second output 41, commands the switch 8 to switch to the second contact

12. thus connecting the manual valve control 6 to the actuator member 67 of the turbine 100. By connecting the power regulator 66 to the manual valve control 8 of the turbine 100, the pressure corrector 6 is deactivated. The same effect can be achieved by manually adjusting the switch 6 from the first contact 14 to the second contact 15. The pressure corrector 6 can only be disabled by the two methods described above.

If the nominal steam pressure γ of the main steam collector 70 is restored, for example, by restoring the operation of the main circulation pumps, the Rg status signal of the main circulation pumps is canceled and the logic member 6 commands the switch 2 to open and simultaneously switch the switch 6 to the home position.

Claims (1)

Connection of an electronic turbine control loop to a saturated steam, consisting of a pressure corrector, at least one switch and one switch, a logic member and a pressure analyzer, characterized in that a pressure corrector input (10) is connected to the output (50) of the pressure analyzer (5). 1) a pressure whose output (11) is connected to a switch (2) whose contact (13) is connected to a first summation member (6) of the power control loop, whereas the switch (2) is connected to a first output (40) of the logic element (4), the inputs (42) of which are connected to the evaluation circuit of the circulation pumps of the nuclear reactor, and the second output (41) of the logic element (4) is connected to the power control loop switch (3).