DE2025975A1 - Duty regulator for boiling water reactor - regulating both - time and power behaviour - Google Patents

Abstract

A boiling water reactor is regulated in terms of both time and power demand by the positioning of its control rods with reference to its coolant circulation. The regulator for the control rods includes an integrating computer which solves the multi group diffusion equation on the bases of secondary homogenised three dimensional group constants related both to the true reactor geometry and the nuclear feed back. Smooth overshoot free control and optimum utilisation of fuel are ensured.

Description

From regulation of the time behavior and the load behavior of boiling water reactors The operation of nuclear reactors makes a large number of control measures necessary. One of the most important is the regulation of the burn-up of the inventory of fissile materials and the load sequence control, the need to regulate the burn-up results due to the steady decrease in the inventory of fissile materials during the operation of the Reactor.

In the case of boiling water reactors, an even burn-up is common Achieved solely by changing the tax rod positions. This is done in such a way that with the help of externally performed neutron physical calculations of From time to time the burned-up state of the reactor was determined and a so-called control rod driving program is set up. In this control stick drive program it is a specification of the next control stick travel steps and a Selection of the control rods to be moved. At least some of these selected control rods is connected to the automatic power control of the reactor and is additionally proceed based on the load request signal of this regulation.

This procedure is tied to an external data center and requires constant cooperation and control by reactor specialists.

This creates the risk of incorrect operation as a result of human Failure.

The main reason for the fact that until now there is no automatic Burn control for a boiling water reactor lies in the quality of the control rod drive program justified. It cannot be created precisely enough with previously known means.

The need for load sequence control is based on the fact that Large nuclear power plants must be able to cope with the time-varying electricity demand curve and follow the network balancing instructions of the load balancer. The resulting Load requests are often periodic, so that for a specific point in time lets determine what power the power plant must drive. It is known that at such a load change operation, the xenon concentration in the reactor fuel is unsteady and that this in turn results in a physically unsteady behavior of the reactor results.

the rough load change is now nourished by a corresponding change in the Throughput and the control staff is set, results there is also the need to compensate for the xenon effects so that the Output is kept constant and the design limits (hot spots) are not exceeded will. The adjustment of these xenon effects is only possible with the help of the control rods, since only these have a noticeable influence on the hot spots.

In older reactors it is done by manually moving control rods; a possibility that is not available with newer systems because the design limits of the Reactor are easily exceeded due to the higher power density, so that human failure of the reactor operator to damage the reactor core can lead.

The xrfindar has set itself the task of creating a fully automatic Adjustment of the time behavior and the load behavior of boiling water reactors with the help of the control rods, taking into account the coolant circulation. The controller required for this must have a transmission behavior that matches the physical Conditions of boiling water reactors is adapted in such a way that the fire control and the load sequence control fully automatically without intervention by the operating personnel the eactor can be done. The controller should therefore also deal with those previously handled externally Take on regular tasks. He has to cope with a certain arithmetic work and generate corresponding signals, either directly or after digital-to-analog conversion the actuators work.

This object is achieved in that the control rods are fully automatic during reactor operation by a controller with an integrated arithmetic unit Stelbverte can be adjusted by reading the multi-group diffusion equation in the controller's arithmetic unit on the basis of second homogenized group constants in three dimensions and taking into account the real reactor geometry and the nuclear feedbacks are obtained.

The following are based on the considerations that make up the present invention led, the most essential measures according to the invention explained.

To solve the problem it must be possible to use an electronic Data processing system for controlling the burn-up, stationary and for load sequence control perform time-dependent neutron diffusion calculations with high accuracy. These It only has to solve the task in certain burn-up spans, i.e. time steps, and these Experience has shown that time spans are so large that the computing time of the computer does not matter much.

Namely, it is due to the fact that there is an automatic fine control the control rods gives with the help of the load request signal, not necessary a continuous one To make advance determination of the control rod departure steps. Rather, it is enough and fine adjustment is compatible with compliance with safety and design limits to be left to the load regulator, who thus becomes part of the regulator.

The arithmetic unit of the controller determines the burn-up range mentioned above the necessary to compensate for the burn-up for each control rod required for this End position determined. Such an increase is under a burn-up range of the burn-up understood, which allows the necessary to achieve them Determine the final values of the tax rods by means of a one-time calculation process, so that there are no diffusion calculations for the intermediate values of the tax rod positions more need to be done.

In boiling water reactors with step-by-step adjustable control rod drives the step size is about 15 cm. To reach the end position during a Burning span are usually run through two to six such step sizes.

With boiling water reactors with infinitely adjustable control rods As practice shows, similar step sizes are observed.

In principle, the same requirements apply to load sequence control as with the combustion control and, like this, it is a reactivity control.

However, it is now added to the problem that various design parameters of the reactor such as coolant flow rate) and xenon poisoning from their full load values differ and can even become transient. Ss ground through, for example a time-variable xenon concentration locally the hot spots, i.e. the Actual performance distribution affected. As with a boiling water reactor In addition to the control rods, the throughput values are also variable, are now two Controlled variables can be influenced. This is circumvented9 by external for each partial load condition the throughput values are determined, which is possible without the controller function to affect9 because the throughput of a boiling water reactor has little effect has on the power distribution. With this, load sequence control is in principle on again a control rod control reduces the throughput setting which is dependent on the load signal does not need to be dealt with in more detail here.

As before, there are special requirements for load sequence control indicated because of the xenon effects. The puncture and task distribution of the regulator however, remains the same as with the combustion control, only the time dependency the xenon concentration is to be incorporated into the calculation of the control rod drive program. The neutron diffusion calculations become unsteady and therefore more complicated, Da however, it is assumed that the load change plan is available for a longer period of time this case can be covered by the automatic load sequence control - exists here too there is enough time for the arithmetic work in the controller's arithmetic unit. That for the control rod driving program to be created for load sequence control applies to the tknsient The transition from one stationary load condition to another is therefore relatively short-term. Similar to the combustion control, no continuous staff position values are required here either be created, and it suffices to determine the positions of the staff in certain, from experience to create upcoming time steps. You can switch between these time steps directly the intervene load-signal-dependent load regulators.

The calculation of the tax deduction values is carried out in all cases indirect, i.e. positional values are assumed and it is determined whether they are the Satisfy the reactivity requirement and the safety and design limits. the "Strategy data" necessary for this are obtained by the fact that after each burn-up span, which the computer bridges by setting the control rod drive program, the actual values of the control rod positions from the drives are entered into the computer and together with values for the safety and design limits due to the reactor-internal instrumentation are available at any time, to a "strategy" are processed.

The diffusion calculations necessary to determine the tax rod values are three-dimensional taking into account the real reactor group geometry carried out. This is done on the basis of second homogenized group constants, which are calculated externally in the course of the reactor design and entered into the calculator will. The diffusion calculation for the entire reactor then consists of the solution a multitude of sub-diffusion calculations for partial volumes of the reactor with in each case the same second homogenized group constants and must meet the Xand conditions of the partial volumes. The delimitation of the partial volumes from one another orientates itself according to the formation process of the z: time-hoeogenized group constants according to the geometry of the tractor and happens vertically direction by dividing the active length of the reactor into divisions, their height width match the possible position values of the control rod drives. With solution the diffusion equations for the entire reactor were the nuclear feedbacks included. The solution is shown schematically below.

An exemplary embodiment of the invention will now be described with reference to the drawing described.

The drawing shows the reactor core 1 with a schematic representation the control rod drives 6 and the circulation pumps 7. The reached in the reactor core 1 Power is measured with the aid of instrumentation inside the reactor (not shown) measured and determined in a device for determining the performance. 2 as well as on a comparison element 3 is given for the setpoint / actual value comparison, where the comparison with the power setpoint entered in setpoint input 4 is carried out, After this comparison, if the actual value deviates from the setpoint by more than a specified value This is signaled to a controller 5. The controller 5 consists of one Arithmetic unit 5 'and a load control device 5 ", the result signal from the setpoint-actual value comparison in the comparison element 3 is checked in the arithmetic unit 5 '. Depending on the deviation of the actual value from the setpoint, the arithmetic unit 5 'selects a subroutine for the load sequence control or for the combustion control.

With the subroutine selected in this way, the input variables for the load control device 511 determined. The arithmetic unit 5 'has previously in the case of Combustion control based on the current tax rod values at the end of the last Burning period determines the control rod drive program for the next burning period. In the case of load sequence control, a specific value is initially entered from the setpoint input 4 speed entered in the setpoint input 4 in tabular form as an analog signal for the circulation pumps 7 transferred to this. At the same time, the arithmetic unit 5 ' the appropriate subroutine selected and used also control rod values, Cr1 before were determined by the arithmetic unit 59 with The load control device 5 ″ regulates the control rod drives according to these control rod adjustment values 6 on registration of the arithmetic unit 5 continuously.

This is done with the aid of the instrumentation inside the reactor (not shown) continuously checked by the arithmetic unit 59 whether the design limits of the reactor during of the control process have not been exceeded. If necessary, the arithmetic unit 51 corrected accordingly via the load control device 59 '. Is in reactor 1 the If the desired load value is reached, then the control process is in the case of combustion control terminated In the case of load sequence control, the calculator logs in 5 'Control rods moved until a steady state reactor is reached or until a new setpoint is requested from setpoint input 4.

Claims (6)

Patent claims e Adjustment of the time behavior as well as the load behavior of the water reactors with the help of the control rods, taking into account the coolant circulation, thereby characterized in that the control rods are fully automatic during reactor operation adjusted by such control values by a controller (5) with an integrated arithmetic unit (5 ') are obtained by solving the multi-group diffusion equation in the arithmetic unit (5 ') of the regulator (5) on the basis of second homogenized group constants in three dimensions and taking into account the real reactor geometry as well as the nuclear feedback can be obtained. 2. house control of the time behavior as well as the load following behavior of Boiling water reactors according to Claim 1, characterized in that the regulator (5) uses a reactor model for the application of the E-group diffusion equation, which the cross-sections within bundle cells and / or control rod cells combined to form two homogenized group constants. 3. Adjustment of the time behavior as well as the load following behavior of Boiling water reactors according to Claims 1 and 2, characterized in that the Controller (5) for determining the control rod shutdown signals as nuclear feedback the xenon feedback, the Doppler effect and the feedback due to the temperature dependence the coolant density. 4. Adjustment of the time behavior as well as the load following behavior of Boiling water reactors according to claims 1 to 3, characterized in that the Regulator (5) by taking into account the real reactor geometry of each individual control rod adjusted independently of the others. 5. Adjustment of the time behavior as well as the load following behavior of Boiling water reactors according to Claims 1 to 3, characterized in that the Controller t5) individual control rod groups by taking into account the real reactor geometry adjusted independently of each other. 6. Adjustment of the time behavior as well as the load following behavior of Boiling water reactors according to Claim 1 or one of the following, characterized in that that to determine the control rod travel program in the controller's arithmetic unit technical requirements for a control rod driving strategy entered are.