KR101250111B1 - An Estimation Method of Fuel Rod Molten Mass in Horizontal Channel Type Reactor - Google Patents

Abstract

The present invention compares the fuel cladding tube temperature and the fuel temperature with a set value of the cladding tube and the melting temperature of the fuel tube to determine the break point of the cladding tube and the fuel, and to determine the total melt mass of the outer ring using a filtering technique and a circulation model. Applying the same method to calculate the total melt mass of the intermediate ring, the total melt mass of the inner ring, and the melt mass of the center fuel rod to add the melt mass of each of the outer ring, the intermediate ring, the inner ring, and the center fuel rod. The present invention relates to a cladding tube and a nuclear fuel melt mass calculation method of a horizontal pipeline reactor equipped with:

Description

An Estimation Method of Fuel Rod Molten Mass in Horizontal Channel Type Reactor

The present invention compares the fuel cladding tube temperature and the fuel temperature with a set value of the cladding tube and the melting temperature of the fuel tube to determine the break point of the cladding tube and the fuel, and to determine the total melt mass of the outer ring using a filtering technique and a circulation model. Applying the same method to calculate the total melt mass of the intermediate ring, the total melt mass of the inner ring, and the melt mass of the center fuel rod to add the melt mass of each of the outer ring, the intermediate ring, the inner ring, and the center fuel rod. The present invention relates to a cladding tube and a nuclear fuel melt mass calculation method of a horizontal pipeline reactor equipped with:

A typical horizontal pipeline reactor is characterized by hundreds of fuel pipes arranged horizontally, each containing about a dozen fuel bundles, each of which consists of dozens of fuel rods in a ring.

The fuel rod is a zirconium alloy tube containing a sintered natural uranium dioxide as a fuel.

The horizontal pipeline reactor is shown in Figure 1, the reactor system is a closed circuit consisting of the reactor, fuel pipe, inlet capillary, outlet capillary, coolant pump and steam generator.

The reactor is filled with hard water, which is used to slow down neutrons, with hundreds of fuel pipes arranged horizontally, and inside, heavy water, a coolant, is used to cool the fuel rods.

The hot heavy water from the fuel pipe collects in the outlet capillary, passes heat through the steam generator, and transfers heat to the secondary side. The low temperature heavy water passes through the inlet capillary by the coolant pump and enters the reactor again through the fuel pipe.

2 is a cross-sectional view of one fuel pipe, which is a horizontal pipe in which a nuclear fuel bundle is inserted. The fuel pipe is largely composed of a double structure of an outer pipe and a pressure pipe, and is filled with a gas that performs a heat transfer minimization function therebetween.

Inside the pressure tube are the fuel rods that make up the fuel bundle.The center fuel rod, the inner ring consisting of six fuel rods, the middle ring consisting of 12 fuel rods, and the outer ring consisting of 18 fuel rods are arranged in the center. Fuel rods are arranged, and the nuclear fuel service is a structure in which heavy water, a coolant, passes through.

3 is a configuration diagram of a nuclear fuel bundle that enters a fuel pipe. Nuclear fuel rods are sealed by inserting dozens of fuel sinters of natural uranium into a zirconium alloy tube called a nuclear fuel rod cladding tube. Dozens of such fuel rods are configured in the shape of a fuel bundle in the form of a ring by a fuel-end junction plate.

The method for evaluating the safety of horizontal pipeline reactors characterized by such a structure is assumed to be a possible accident, comprehensively analyzes the various scenarios resulting from the accident, and finally determines the degree to which the accident affects the safety of the reactor. To analyze.

The most serious and serious of the many accidents is the melting of nuclear fuel, which is caused by the melting of some fuel rods due to a very high temperature inside the reactor.

In an accident scenario after melting, the melt flows out of the fuel pipe through the broken fuel pipe and damages the reactor internal structure, preventing it from functioning and radioactive material contained in the melt leaking out through the moderator system. There is a problem.

Therefore, it is necessary to accurately assess the mass of the fuel rod melt after the accident in order to accurately determine whether the reactor can be shut down normally, the amount of external leakage of radioactive material, the route of the melt, etc., and to minimize the cost of follow-up due to the accident. do.

However, the conventional calculation method, as shown in FIG. 4, covers only one fuel rod located at the top of each ring in the inner ring, the middle ring, and the outer ring constituting the fuel bundle of each fuel pipe. If the temperature of the fuel is equal to or higher than the melting temperature (T _{c, melt} and T _{f, melt} ) of the cladding and fuel determined in the design of the fuel rod, then assume that all fuel rods in the ring melt. Therefore, this method has a problem that the melt mass is excessively calculated.

The problem to be solved by the present invention is to accurately evaluate the amount of melt, to more accurately analyze the impact of some radioactive material to the atmosphere to the public, and to minimize the cost of the optimization plan and accident measures for the radiological protection .

Another problem to be solved by the present invention is to determine the molten mass of each fuel rod in order from the highest fuel rod to the lowest fuel rod using a filtering technique and a circulation model, the sum of the melt mass of each fuel rod, the outer ring, the intermediate ring and the inner ring To determine the total melt mass, determine the melt mass of the center fuel rod, and accurately determine the melt mass.

Another problem to be solved by the present invention is to accurately evaluate the nuclear fuel rod melt mass evaluation for the fuel cladding and the fuel, to accurately determine the degree of damage to the reactor shutdown system due to the melt flowing out of the broken cladding after the accident, accordingly It is to greatly reduce the investment cost for the secondary facility of additional reactor stop system by optimizing the stop capacity margin which is necessarily accompanied in the design of stop system.

The problem solving means of the present invention is to set the melting temperature of the cladding stored in the memory by analyzing the fuel rod cladding temperature by thermal hydraulic analysis methodology of data such as pressure, flow rate and temperature, which are the main variables indicating the state of the reactor system after an accident Determining the point of failure of the cladding tube by comparison with the values, calculating the total melt mass of the cladding tube against the outer ring using filtering techniques and circulation models, and applying the same method to A method for calculating the nuclear fuel rod melt mass of a horizontal pipeline reactor comprising calculating the total melt mass and calculating the melt mass of the center cladding tube and summing the melt mass of each of the outer ring, intermediate ring, inner ring and center cladding tube. To provide.

Another problem solving means of the present invention is to set the value of the fuel melting temperature stored in the memory by analyzing the fuel temperature by thermal hydraulic analysis methodology data such as pressure, flow rate and temperature, which are the main variables indicating the state of the reactor system after an accident Determining the point of time of nuclear fuel failure, and calculating the total fuel melt mass for the outer ring using filtering techniques and circulation models, and applying the same method to the total fuel melt mass for the intermediate and inner rings. And calculating the melt mass of the center fuel and summing the melt mass of each of the outer ring, the middle ring, the inner ring, and the center fuel. .

Another problem solving means of the present invention sums the calculated total melt mass of the cladding and nuclear fuel of the outer ring, the calculated total melt mass of the cladding and nuclear fuel of the intermediate ring and inner ring, and the total melt mass of the calculated center cladding and nuclear fuel It is to provide a method for calculating the fuel rod melt mass of the horizontal pipeline reactor comprising the step of calculating the total fuel rod (coated tube + fuel) melt mass of the horizontal pipeline reactor.

The present invention aims to more accurately analyze the impact of some radioactive material on the public by evaluating the amount of melt, and to minimize the cost of accident planning and optimization of contingency planning for radiation protection.

Another effect of the present invention is to use the filtering technique and the circulation model to calculate the molten mass of each fuel rod from the top fuel rod to the bottom fuel rod, and the sum of the melt mass of each fuel rod, the total of the outer ring, intermediate ring, inner ring It is to determine the melt mass and to accurately calculate the melt mass of the center fuel rod to minimize economic losses.

Another effect of the present invention is to accurately evaluate the melt mass of the fuel rods for the fuel cladding tube and the fuel, so as to accurately determine the degree of damage to the reactor shutdown system due to the melt flowing out through the broken cladding after the accident, and thus the reactor shutdown. It is to greatly reduce the investment cost for the secondary facility of additional reactor shutdown system by optimizing the margin of stopping capacity that is necessarily accompanied in the system design.

1 is a conceptual view of a horizontal pipeline reactor.
2 is a cross-sectional view of a cladding tube in which a nuclear fuel bundle is inserted.
3 is a schematic diagram of a bundle of nuclear fuel entering a cladding tube.
4 is a conventional fuel rod melt mass evaluation flowchart.
5 is a flow chart of nuclear fuel rod melt mass evaluation through a filtering technique.
Description of the Related Art
10; Fuel line 11; nuclear pile
12; Inlet duct 13; Outlet
14; Coolant pump 15; Steam generator
20; Nuclear fuel rods 21; Outer ring
22; Middle ring 23; Inner ring
24; Center fuel rod 25; Pressure pipe
26; Outer tube 27; Coolant
28; Gas flow
30; Sintered body 31; Nuclear fuel rod cladding
32; Nuclear Fuel Rod Junction Plate
50; Coolant 51; steam
501; Top 502; 2 steps below the top
503; 3 steps below 2 steps

Hereinafter, the present invention will be described in detail. The fuel rod melt mass calculation method of a horizontal pipeline reactor according to the present invention includes comparing the fuel and cladding temperature with a set value of the fuel and cladding melting temperature stored in a memory to determine a fuel and cladding break point.

In addition, the present invention is to determine the total fuel rod (cladding + fuel) melt mass of the outer ring by using a filtering technique and a circulation model, the total fuel rod (cladding + fuel) melt mass of the intermediate ring by applying the same method And calculating the total mass of the fuel rods (covering tube + fuel) of the inner ring and the mass of the center fuel rod and summing the melt mass of each of the outer ring, the intermediate ring, the inner ring, and the center fuel rod. A specific embodiment of the present invention will be described.

<Examples>

An embodiment according to the present invention will be described with reference to the drawings. FIG. 1 schematically shows a horizontal pipeline reactor, and FIG. 2 shows a cross-sectional view of a cladding tube in which a nuclear fuel bundle is inserted.

The present invention calculates the cladding tube and fuel temperature for each position in order to provide the determination data for establishing the optimal follow-up measures after the fuel rod melting by preventing excessive calculation of the fuel rod melt mass of the prior art, and the calculated value is stored in the memory And an error filtering technique, which is regarded as an error and is removed when it is less than the set value compared with the set value for the fuel melting temperature.

In order to filter the temperature of the fuel rods, the present invention provides a circulation model capable of comparing data according to the position of each fuel rod, and includes a calculation step of calculating a melt mass of the fuel rods therefrom. The fuel rod herein includes a cladding tube and a nuclear fuel.

An error filtering technique and a data comparison cyclic model for each location of the present invention will be described with reference to FIG. 5.

5 is a flow chart of total melt mass assessment of nuclear fuel rods through filtering techniques. In FIG. 5, when the coolant 50 of the fuel pipe is partially lost due to an accident, the upper half is filled with steam 51 and the lower half is an embodiment of a nuclear fuel rod outer ring when the coolant 50 is filled. It is shown.

First, the data such as pressure, flow rate, and temperature, which are the main variables representing the state of the reactor system after an accident, are analyzed and calculated by a thermal hydraulic analysis methodology, and the fuel fuel tube temperature at the bottom of the pressure tube obtained from the analysis result is input into the memory. And determining a time point at which the cladding tube is broken by comparing with a set value of the melting temperature (T _{c, melt} ) of the cladding tube.

The next step is to determine when the cladding tube into which the fuel pellet is injected is broken, and based on the failure point of the cladding tube which is determined to be broken, three rings consisting of an outer ring, an intermediate ring and an inner ring of the cladding tube (21 to 21 in FIG. 2). 23) Filtering the temperature of each cladding tube by applying filtering technique and circulation model sequentially from the top to the bottom for the center cladding, and the melting temperature (T _{c, melt} and T _{f, melt} ) Compared to the set value, and when the comparison result is greater than the set value, the fuel rod melt mass for each ring described above is calculated.

The error filtering technique and the cyclic model applied to the present invention will be described in more detail.

In the case of the outer ring cladding of the fuel bundle, in the circulation model, when the initial value N = 0, N = N + 1 to N = 1, and the step N = 1 is the fuel rod at the top (501 in FIG. 5). The temperature of one cladding tube is analyzed and calculated by the above-described thermal hydraulic analysis methodology, and the temperature is obtained. The temperature obtained is compared with the set value of the cladding melting temperature (T _{c, melt} ) stored in the memory. Judgment calculates sheath melt mass and stores the value in memory.

However, if the cladding tube temperature is less than the cladding tube melting temperature (T _{c , melt} ) _{, the} process proceeds to the next step of comparing the nuclear fuel temperature.

As used herein, the filtering technique is a reduction of the error filtering technique and has the same meaning.

At this time, the coating tube melting temperature (T _{c , melt} ) is stored in the memory with the analysis program designed and manufactured according to the present invention.

In the same way as the method of calculating the melt of the cladding tube when the initial value N = 0, that is, N = N + 1 = 1 by applying the circulation model to the cladding tube, the state of the reactor system after the accident occurred for the nuclear fuel. Nuclear fuel temperature is obtained by analyzing the hydrodynamic methodology such as pressure, flow rate and temperature, which are the main variables.

Comparing the obtained fuel temperature and the set value of the fuel melting temperature (T _{f , melt} ) stored in the memory and compares with each other, the fuel melt mass is calculated and stored in the memory.

On the other hand, when the cladding or fuel temperature of the fuel rod is less than the set value of each melting temperature (T _{c, melt} and T _{f, melt} ) stored in the memory, it is regarded as an error and excluded from the melt mass calculation.

Next, when N = 1, N = N + 1 to N = 2, the step of N = 2 is the cladding temperature for each of the two fuel rods located in the second stage (502 in Fig. 5) just below the top end. Compared to the set value of the cladding tube melting temperature (T _{c , melt} ) stored in the memory, if the value is equal to or higher than the set value, it is regarded as molten and the cladding tube melt mass is calculated and stored.

If the fuel temperature located inside the cladding tube of step N = 2 is also higher than the set value of the fuel melting temperature (T _{f , melt} ) stored in the memory as in the method of comparing the cladding tube temperature, the fuel melt mass is calculated. Save the value.

On the other hand, if the cladding or fuel temperature of the fuel rod is less than the set values of the melting temperatures (T _{c , melt} and T _{f , melt} ) respectively stored in the memory, it is regarded as an error and excluded from the melt mass calculation.

Next, when N = 2, N = 2 + 1 to N = 3, and the stage where N = 3 is two nuclear fuel rods of three stages (503 of FIG. 5) located below the second stage 502, In the same way as N = 1 and N = 2, if the fuel rod cladding or fuel temperature is less than the set values of the melting temperatures (T _{c , melt} and T _{f , melt} ) respectively stored in the memory, they are filtered out.

Repeatedly applying the above-described method, N = 9 and N = 10 for the outer ring of Figure 5, that is, the calculation of the molten mass for the cladding tube and the nuclear fuel sequentially to the lowest fuel rod of the outer ring And storing the calculated value in memory.

After the calculation of the melt mass for the cladding tube and the nuclear fuel by applying the filtering technique and the circulation model to the outer ring, the melt mass of the cladding tube and the fuel for the intermediate and inner rings is calculated by applying the same filtering technique and the circulation model. And store the value in memory.

In FIG. 5, the molten mass of the cladding tube and the fuel is calculated by applying a filtering technique and a circulation model to one fuel rod located at the center, and the values are stored in a memory.

The sum of the melt mass for each of the cladding and the nuclear fuel calculated in the above step is used to calculate the total melt mass of the fuel rods of the horizontal pipeline reactor according to the present invention.

The calculation of the melt mass for the cladding tube and the nuclear fuel was simultaneously described for easy understanding of the above description, but may be described in order based on the flowchart of FIG. 4.

The technical configuration according to the present invention will be described in more detail.

In the method for calculating the cladding tube melt mass of a horizontal pipe-type reactor, the outer ring is obtained by calculating the cladding tube temperature and comparing the set point value of the cladding temperature stored in the memory to determine the breakage point of the cladding tube when the cladding tube is above the melting temperature. Calculating the total cladding tube melt mass of the intermediate ring and the inner ring, and calculating the center cladding tube melt mass of the intermediate ring and the inner ring. Summing the sheath total melt mass of the ring and center.

In the method of calculating the fuel melt mass of a horizontal pipeline reactor, the fuel temperature is calculated and compared with the set value of the fuel melting temperature stored in the memory to determine the fuel failure time when the fuel is above the melting temperature of the fuel. Comprising the step of calculating the total fuel melt mass, and calculating the total fuel melt mass of the intermediate ring and the inner ring, the step of calculating the center fuel melt mass, the calculated outer ring, intermediate ring, inner ring And summing the total fuel mass of the fuel in the center.

In the method for calculating the cladding tube melt mass of a horizontal pipeline type reactor, the outer ring is obtained by calculating the cladding tube temperature and comparing the set point value of the cladding temperature stored in the memory to determine the breakage point of the cladding tube when the cladding tube is above the melting temperature. Calculating the total cladding tube melt mass of the intermediate ring and the inner ring, and calculating the center cladding tube melt mass of the intermediate ring and the inner ring. Through the step of summing the total melt mass of the cladding of the ring and the center, calculating the fuel temperature and comparing the set value of the fuel melting temperature stored in the memory to determine the fuel failure time when the fuel is above the melting temperature of the fuel. Computing the total fuel melt mass of the ring through the steps of calculating the total fuel melt of the intermediate and inner rings After calculating the amount, and through the step of calculating the center fuel melt mass, and through the step of summing the total fuel melt mass of the outer ring, the intermediate ring, the inner ring and the center, the total pipe mass melt mass and Summing up the total fuel melt mass.

That is, the protection scope of the present invention includes the method for calculating any one or two or more of the calculation of the total melt mass of the cladding tube and the nuclear fuel, the calculation of the total melt mass of the coating tube, and the calculation of the total fuel melt mass of the nuclear fuel.

The present invention compares the fuel cladding tube temperature and the fuel temperature with a set value of the cladding tube and the melting temperature of the fuel tube to determine the break point of the cladding tube and the fuel, and to determine the total melt mass of the outer ring using a filtering technique and a circulation model. Applying the same method to calculate the total melt mass of the intermediate ring, the total melt mass of the inner ring, and the melt mass of the center fuel rod to add the melt mass of each of the outer ring, the intermediate ring, the inner ring, and the center fuel rod. It is highly industrially available because it provides accurate analysis of cladding pipe and nuclear fuel melt mass calculation method of horizontal pipeline type reactor equipped with the system, minimizing the cost of contingency planning and minimizing accidents.

Claims (9)

A computer-readable recording medium having a method of calculating a cladding tube melt mass calculation program inside each nuclear fuel assembly in a horizontal pipeline reactor.
Calculating a cladding tube temperature by applying a thermohydraulic analysis methodology, and comparing the calculated cladding tube temperature with a set value of the cladding tube melting temperature stored in a computer memory to determine a cladding tube break point when the cladding tube melting temperature is higher than the cladding tube melting temperature;
Calculating a total sheath melt mass of the outer rings;
Calculating a total sheath melt mass of the intermediate rings and the inner rings;
Calculating a center cladding melt mass; And
Including the calculated outer ring, the intermediate ring, the inner ring and the coating tube melt mass of the center; including,
The calculation of the melt mass of the outer ring, the intermediate ring, the inner ring, and the center is performed by a filtering technique and a circulation model. Recordable media.
A computer-readable recording medium having recorded thereon a method for calculating a fuel melt mass in each fuel assembly in a horizontal pipeline reactor.
Calculating a fuel temperature by applying a thermal hydraulic methodology, and comparing the calculated fuel temperature with a set value of a fuel melting temperature stored in a computer memory to determine a fuel failure time when the fuel temperature is higher than the melting temperature of the fuel;
Calculating a total fuel melt mass of the outer rings;
Calculating a total fuel melt mass of the intermediate rings and the inner rings;
Calculating a center fuel melt mass; And
Summing the total fuel melt mass of the calculated outer ring, middle ring, inner ring and center;
The calculation of the melt mass of the outer ring, the intermediate ring, the inner ring, and the center is performed by a filtering technique and a circulation model. Recordable media.
A computer-readable recording medium having recorded thereon a method for calculating a fuel rod melt mass inside a fuel assembly in a horizontal pipeline reactor.
Calculating a cladding tube temperature by applying a thermohydraulic analysis methodology, and comparing the calculated cladding tube temperature with a set value of the melting temperature of the cladding tube stored in the computer memory to determine a cladding tube break point when the cladding tube is above the melting temperature of the cladding tube;
Calculating a total sheath melt mass of the outer ring;
Calculating a total sheath melt mass of the intermediate rings and the inner rings;
Calculating a center cladding melt mass;
Summing the calculated outer ring, middle ring, inner ring and sheath total melt mass of the center;
Calculating a fuel temperature by applying a thermal hydraulic methodology, and comparing the calculated fuel temperature with a set value of a fuel melting temperature stored in a memory to determine a fuel failure time when the fuel temperature is higher than the melting temperature of the fuel;
Calculating a total fuel melt mass of the outer ring;
Calculating a total fuel melt mass of the intermediate rings and the inner rings;
Calculating a center fuel melt mass;
Summing the total fuel melt mass of the calculated outer ring, middle ring, inner ring and center; And
Including the total melt mass of the cladding tube and the total melt mass of the nuclear fuel;
The method for calculating the melt mass of each of the outer ring, the middle ring, the inner ring, and the center consists of a filtering technique and a circulation model. Computer-readable recording media.
delete The method according to claim 3,
Computation of the molten mass calculation method of the fuel rod molten mass in the fuel assembly of the horizontal pipeline reactor is characterized in that the calculation of the melt mass of the outer ring, the intermediate ring, the inner ring, and the center is performed for the cladding tube and the fuel. Recordable media.
delete The method according to claim 1,
The calculation of the melt mass of the outer ring, the intermediate ring, the inner ring, and the center is performed on the cladding tube and the nuclear fuel. Recording media.
delete The method according to claim 2,
Calculation of the melt mass of the outer ring, the intermediate ring, the inner ring, and the center is performed on the cladding tube and the fuel, and the method for calculating the fuel melt mass in the fuel assembly of the horizontal pipeline reactor is recorded. Recording media.

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