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What is Nuclear Reactor

Article Summary & FAQs

What is a nuclear reactor?

Generally, a nuclear reactor is a device to initiate and control a self-sustained nuclear chain reaction. Since nuclear reactors are used in nuclear power plants, research facilities, or nuclear-propelled ships, their output is thermal energy, or they can be used as a source of neutron radiation.

Key Facts

  • The key component of nuclear reactors is a reactor core. The reactor core is a bounded region where neutron multiplication and chain reactions occur. The reactor core contains the nuclear fuel (fuel assemblies), the moderator, and the control rods.
  • The main product of research reactors is usually a neutron flux, which is then used, for example, for medical purposes or research purposes.
  • Nuclear reactors in nuclear power plants are “only” used to generate large amounts of heat. This heat is used to generate steam which drives a steam turbine connected to a generator that produces electricity.
  • The most common nuclear reactors are light water reactors (LWR), where light water is used as a moderator.
  • The key components common to most PWR types of nuclear reactors are:
  • A typical reactor may contain about 100 tonnes of enriched uranium (i.e., about 113 tonnes of uranium dioxide).
  • Typical reactor nominal thermal power is about 3400MW, thus corresponding to the net electric output of 1100 MW. Therefore the typical thermal efficiency of its Rankine cycle is about 33%.
  • In nuclear reactors, control rods are used for maintaining the desired state of fission reactions. The basic classification of states of a reactor is according to the multiplication factor. Suppose the multiplication factor for a multiplying system is equal to 1.0. In that case, there is no change in neutron population in time (i.e., the reactor is stable), and the chain reaction will be self-sustaining. This condition is known as the critical state.
How does a nuclear reactor work?
How does a nuclear reactor work?

  • In nuclear reactors, usually, control rods are used for maintaining the desired state, which means a self-sustaining chain reaction.
  • The reaction rate of this chain reaction corresponds to the nominal thermal power.
  • Typical reactor nominal thermal power is about 3400MW, but the heat produced must be continuously removed from the core.
  • For PWRs, the coolant (water) is heated in the reactor core from about 290°C (554°F) to approximately 325°C (617°F) as the water flows through the core.
  • Hot coolant goes to hot legs and is pumped via main coolant pumps into steam generators.
  • In steam generators, this heat is transferred through the walls of these tubes to the lower pressure secondary coolant located on the secondary side of the exchanger, where the coolant evaporates to pressurized steam (saturated steam 280°C; 536°F; 6,5 MPa).
  • This pressurized steam is then routed into the steam turbine, in which steam expands from pressures of about 6 MPa to pressures of about 0.008 MPa.
  • The reactor coolant from the steam generator (primary side) is pumped back into the core through the cold leg, and the process is repeated.
  • A control rod is removed from or inserted into the reactor core to increase or decrease the thermal power.
How to control a nuclear reactor?
How to control a nuclear reactor?

In general, the reactor thermal power and the outlet temperature of the coolant from the reactor core are controlled by manipulating several factors which affect the core’s reactivity. In PWRs, these factors are especially:

  • position of control rods,
  • the concentration of boric acid in the RCS
  • core inlet temperature

A reactor “SCRAM” (or “reactor trip”) is the rapid insertion or fall of the control rods into the core to stop the fission chain reaction. At PWRs, all control rods are usually inserted within two to four seconds.

See also: Reactor Control

How to turn the reactor off and on?
How to turn the reactor off and on?

Reactor Startup

The process of reactor startup is termed criticality approach or startup to minimum load. For the criticality approach, parameters known as estimated critical conditions must be known, and these are target parameters. After criticality is achieved, a positive startup rate is established (the reactor is slightly supercritical), and the power level increases to “minimum load.” This power increase is then stabilized at minimum load by control rod insertion.

Reactor Shutdown

A reactor is considered shut down when subcritical and sufficient shutdown reactivity exists, so there is no immediate probability of secondary criticality.

In general, there are two types of reactor shutdown:

  • Emergency Shutdown – SCRAM. A reactor “SCRAM” (or “reactor trip”) is the rapid insertion or fall of the control rods into the core to stop the fission chain reaction.
  • Gradual Shutdown. Usually, there is no need to stop the chain reaction promptly. The shutdown is normally accomplished by gradually inserting some (or all) of the control rods or by introducing soluble neutron poison (boric acid in case of PWRs) into the reactor coolant.

 

What is reactor safety?
What is reactor safety?

Definition by IAEA:

‘Safety’ is the achievement of proper operating conditions, prevention of accidents, and mitigation of accident consequences, resulting in the protection of workers, the public, and the environment from undue radiation hazards.

nuclear reactor - layout
nuclear reactor - layout

reactor - base load

steam turbine - base load

Definition

Generally, a nuclear reactor is a device to initiate and control a self-sustained nuclear chain reaction. Since nuclear reactors are used in nuclear power plants, research facilities, or nuclear-propelled ships, their output is thermal energy, or they can be used as a source of neutron radiation.

Classification of Nuclear Reactors

thermal vs. fast reactor neutron spectrum
The spectrum of neutron energies produced by fission varies significantly with certain reactor designs. Thermal vs. fast reactor neutron spectrum

From the physics point of view, the main differences among reactor types arise from differences in their neutron energy spectra. The basic classification of nuclear reactors is based upon the average energy of the neutrons, which cause the bulk of the fissions in the reactor core. From this point of view, nuclear reactors are divided into two categories:

  • Thermal Reactors. Almost all of the current reactors built to date use thermal neutrons to sustain the chain reaction. These reactors contain a neutron moderator that slows neutrons from fission until their kinetic energy is more or less in thermal equilibrium with the atoms (E < 1 eV) in the system.
  • Fast Neutron Reactors. Fast reactors contain no neutron moderator and use less-moderating primary coolants because they use fast neutrons (E > 1 keV) to cause fission in their fuel.

 

Types of Nuclear Reactors

The main conventional types of nuclear reactors are:

Types of Nuclear Reactors
Source: world-nuclear.org

The most common nuclear reactors are light water reactors (LWR), where light water is used as a moderator. LWRs are divided into two categories:

  • Pressurized water reactors (PWR) – are characterized by a high-pressure primary circuit (to keep the water in a liquid state)
  • Boiling water reactors (BWR) – are characterized by controlled boiling in the primary circuit

Principle of operation of PWR-type reactor

Nuclear reactor - WWER 1200
Nuclear reactor and primary coolant system of WWER-1200.
Source: http://www.bellona.ru/

Pressurized water reactors use a reactor pressure vessel (RPV) to contain the nuclear fuel, moderator, control rods, and coolant. They are cooled and moderated by high-pressure liquid water (e.g., 16MPa). At this pressure, water boils at approximately 350°C (662°F). The inlet temperature of the water is about 290°C (554°F). The water (coolant) is heated in the reactor core to approximately 325°C (617°F) as the water flows through the core. As it can be seen, the reactor has approximately 25°C subcooled coolants (distance from the saturation).

The hot water leaves the pressure vessel through the hot leg nozzle and is looped through a steam generator, which heats a secondary loop of water to steam that can run turbines and generators. Secondary water in the steam generator boils at a pressure of approximately 6-7 MPa, which equals 260°C (500°F) saturated steam. Typical reactor nominal thermal power is about 3400MW, thus corresponding to the net electric output of 1100 MW. Therefore the typical efficiency of the Rankine cycle is about 33%.

See also: Types of Nuclear Reactors

Main Components of Nuclear Reactor

The key components common to most PWR-type nuclear reactors are:

  • reactor materials
    The body of the reactor vessel is constructed of high-quality low-alloy carbon steel. To minimize corrosion, all surfaces that come into contact with reactor coolant are clad with a minimum of about 3 to 10 mm of austenitic stainless steel (e.g., 304L).

    Nuclear reactor core. The reactor core is a bounded region where neutron multiplication occurs and where a chain reaction takes place. The reactor core contains the nuclear fuel (fuel assemblies), the moderator, and the control rods.

  • Reactor pressure vessel. The reactor pressure vessel is the pressure vessel containing the reactor core and other key reactor internals. It is a cylindrical vessel with a hemispherical bottom head and a flanged and gasketed upper head. The bottom head is welded to the cylindrical shell, while the top head is bolted to the cylindrical shell via the flanges. The top head is removable to allow for the refueling of the reactor during planned outages.
  • Neutron reflector. The reactor core is surrounded by a neutron reflector or reactor core baffle. The reflector reduces the non-uniformity of the power distribution in the peripheral fuel assemblies, reduces neutron leakage, and reduces a coolant flow bypass of the core.
  • Lower support structure.
  • Surveillance capsule assembly. The capsules contain reactor vessel steel specimens obtained during vessel fabrication and are withdrawn periodically from the reactor vessel.
  • Core support barrel. The core barrel belongs to the lower core support structure because it houses a reactor core.
  • Upper guide structure assembly. 

Reactor Control

In general, the reactor thermal power and the outlet temperature of the coolant from the reactor core are controlled by manipulating several factors which affect the core’s reactivity. In PWRs, these factors are especially:

  • position of control rods,
  • the concentration of boric acid in the RCS
  • core inlet temperature

These three parameters determine the reactivity of the reactor system. A control rod is removed from or inserted into the reactor core to increase or decrease the reactivity of the reactor (increase or decrease the neutron flux).

See also: Reactor Control

Reactor Criticality

The basic classification of states of a reactor is according to the multiplication factor as eigenvalue, which measures the change in the fission neutron population from one neutron generation to the subsequent generation.

  • Reactor criticality
    Reactor criticality. A – a supercritical state; B – a critical state; C – a subcritical state

    keff < 1. Suppose the multiplication factor for a multiplying system is less than 1.0. In that case, the number of neutrons decreases in time (with the mean generation time), and the chain reaction will never be self-sustaining. This condition is known as the subcritical state.

  • keff = 1. If the multiplication factor for a multiplying system is equal to 1.0, then there is no change in neutron population in time, and the chain reaction will be self-sustaining. This condition is known as the critical state.
  • keff > 1. If the multiplication factor for a multiplying system is greater than 1.0, then the multiplying system produces more neutrons than are needed to be self-sustaining. The number of neutrons increases exponentially in time (with the mean generation time). This condition is known as the supercritical state.

See also: Reactor Criticality

Example – How to Change Power of Nuclear Reactor

During any power increase, the temperature, pressure, or void fraction change, and the reactivity of the core changes accordingly. It is difficult to change any operating parameter and not affect every other core property. Since it is difficult to separate all these effects (moderator, fuel, void, etc.), the power coefficient is defined. The power coefficient combines the Doppler, moderator temperature, and void coefficients. It is expressed as a change in reactivity per change in percent power, Δρ/Δ% power. The value of the power coefficient is always negative in core life. Still, it is more negative at the end of the cycle, primarily due to the decrease in the moderator temperature coefficient.

reactor power - 75 to 100 of rated powerLet’s assume that the reactor is critical at 75% of rated power and that the plant operator wants to increase power to 100% of rated power. The reactor operator must first bring the reactor supercritical by inserting a positive reactivity (e.g., by control rod withdrawal or boron dilution). As the thermal power increases, moderator temperature and fuel temperature increase, causing a negative reactivity effect (from the power coefficient), and the reactor returns to the critical condition. Positive reactivity must be continuously inserted (via control rods or chemical shim) to keep the power increasing. After each reactivity insertion, the reactor power stabilizes proportionately to the reactivity inserted. The total amount of feedback reactivity that must be offset by control rod withdrawal or boron dilution during the power increase (from ~1% – 100%) is known as the power defect.

Let assume:

  • the power coefficient:                 Δρ/Δ% = -20pcm/% of rated power
  • differential worth of control rods:    Δρ/Δstep = 10pcm/step
  • worth of boric acid:                                      -11pcm/ppm
  • the desired trend of power decrease:              1% per minute

75% → ↑ 20 steps or ↓ 18 ppm of boric acid within 10 minutes → 85% → next ↑ 20 steps or ↓ 18 ppm within 10 minutes → 95% → final ↑ 10 steps or ↓ 9 ppm within 5 minutes → 100%

Fuel Consumption of Nuclear Reactor

Consumption of a 3000MWth (~1000MWe) reactor (12-month fuel cycle)

It is an illustrative example, and the following data do not correspond to any reactor design.

  • A typical reactor may contain about 165 tonnes of fuel (including structural material)
  • A typical reactor may contain about 100 tonnes of enriched uranium (i.e., about 113 tonnes of uranium dioxide).
  • This fuel is loaded within, for example, 157 fuel assemblies composed of over 45,000 fuel rods.
  • A common fuel assembly contains energy for approximately 4 years of operation at full power.
  • Therefore about one-quarter of the core is yearly removed from the spent fuel pool (i.e., about 40 fuel assemblies). At the same time, the remainder is rearranged to a location in the core better suited to its remaining level of enrichment (see Power Distribution).
  • The removed fuel (spent nuclear fuel) still contains about 96% of reusable material (must be removed due to decreasing kinf of an assembly).
  • The annual natural uranium consumption of this reactor is about 250 tonnes of natural uranium (to produce about 25 tonnes of enriched uranium).
  • The annual enriched uranium consumption of this reactor is about 25 tonnes of enriched uranium.
  • The annual fissile material consumption of this reactor is about 1 005 kg.
  • The annual matter consumption of this reactor is about 1.051 kg.
  • But it corresponds to about 3 200 000 tons of coal burned in coal-fired power plants per year.

See also: Fuel Consumption

Material Problems and Challenges of Nuclear Reactors

The main problems or rather challenges that must be taken into account when designing reactors are:

See also: Material Problems of Nuclear Reactors

Special Reference: Reactor Pressure Vessel Status Report, U.S. NRC. NUREG-1511. Office of Nuclear Reactor Regulation U.S. Nuclear Regulatory Commission, Washington, 1994.

Did you know?

The world’s first nuclear reactor operated about two billion years ago. The natural nuclear reactor formed at Oklo in Gabon, Africa, when a uranium-rich mineral deposit became flooded with groundwater that acted as a neutron moderator, and a nuclear chain reaction started. These fission reactions were sustained for hundreds of thousands of years until a chain reaction could no longer be supported. This was confirmed by the existence of isotopes of the fission-product gas xenon and by different ratios of U235/U238 (enrichment of natural uranium).

This phenomenon was discovered in 1972 at Oklo in Gabon, Africa.

See previous:

Reactor Types

See above:

Nuclear Power Plant

See next:

Reactor Core