A Primer on Nuclear Safety: 1.4 Complexity

1.4 Complexity

If reactors are able to operate in unsafe conditions, there is an open invitation for an accident to happen. Light water reactors are complex systems. The one billion electric watts reactors so beloved by the civilian nuclear industry from the 1970’s onward, are large and very complex systems. Things can go wrong with them, go badly wrong due to seemingly minor design features involving secondary systems.

Reactors ought to be built so that safety features prevent the operation of the reactor if safety systems are not functioning, and furthermore operators should not have the power to prevent system shut down for safety reasons. People make mistakes. If you give people the power to make mistakes, you ought to assume they will. To take away from people the power to operate a reactor under conditions in which it is unsafe to do so, is to “fool proof” the reactor.

Unfortunately it is quite possible to engineer reactors with deeply flawed safety systems. Sometimes the flaws can be simple, but some very dangerous flaws are complex. Imagine the existence of multiple minor design flaws in different systems, none of which are sufficient by themselves to create a major problem. But in combination they can trigger a serious accident.

For example safety requires back up systems. Let us consider some design features of the Pressurized Water Reactor. Coolant water flows through the reactor, and picks up heat produced by nuclear fission. The coolant then flows away from the reactor, carrying the heat with it. Water in a reactor is like water in a pot, enough heat will make it boil, We saw the when water entered the Oklo natural reactors, the moderating effect of the water triggered a chain reaction, and the heat from the chain reaction made the water boil. In pressurized water reactor the water is kept under pressure. This allows the water to get hotter than its normal boiling point. The higher temperature will allow the reactor to produce power more efficiently, but the gain of efficiency comes at a cost. Both the complexity and the safety problems of reactor systems are magnified by pressurizing hot water inside the reactor.

In a Pressurized Water Reactor, coolant water flows though the reactor, and then out of the reactor into a heat exchange for the steam generator. The heat exchange does two things. It removes heat from the highly pressurized water of the reactor’s primary coolant system. Secondly the heat exchange causes the secondary coolant water to boil and turn into steam. The hot steam flows into a steam turbine where the pressure from the steam turns the turbine.

In order to keep the reactor safe, it must be continuously cooled both during and after a chain reaction. I will presently explain why the after is important. To keep the reactor cooled water must be kept flowing through the primary and secondary coolant systems. If something goes wrong with either the primary or the secondary coolant system, then a third coolant system, the emergency coolant system needs to begin operations immediately.

What can go wrong with the coolant systems? All sorts of things can go wrong. Valves in the systems can get stuck. Pumps can break. Water under high temperature and pressure can leak. The heat exchange between the primary and secondary coolant systems can leak. One system can be taken off line for servicing. A second system is brought on line to provide water, but for some reason it fails. Then a third system, which is, kept in reserve for back up is brought on line, and the unexpected happens, it fails. Suddenly a system, which is vital for the reactors safety and which had triple redundancy has failed.

A widespread power outage can trip a reactor’s safety shutdown system. In order that the reactor cooling system maintain operations pumps have to be kept in operation. Even when the reactor is not operating, heat from the radioactive decay of fission products has to be removed. There are diesel backup generators, but they won’t start. The warranties on the starter batteries were up, but the request for a purchase order got tied up when an administrator took his family on vacation, and no one realized that the request was parked on his unattended desk.

The increasing decay heat from the reactor trips an automatic start up of the emergency coolant system, but the system cannot operate. The emergency coolant system requires electricity from one of the four emergency diesel generators, whose starter batteries have all failed. The electricity is needed to pump emergency coolant water into the reactor’s core. Suddenly a minor administrative glitch, the failure to obtain a signature on a purchase order request, is turning a minor problem into an major accident.

Now if I were writing the plot to an old Hollywood movie, the reactor overheats until it explodes in a huge fireball, followed by a mushroom shaped cloud. Radiation falls on a tiny creature, which immediately undergoes a mutation and begins to grow and learn how to speak Japanese. The creature grins as it contemplates its quest to find Jane Fonda in order to purchase an exercise tape.

Let us take a brief detour into reality. Nuclear safety is about understanding things that can go wrong in complex systems, and preventing em from happening, in so far as that is possible. In so far as it is not possible, nuclear safety is about minimizing damages. Our detour will eventually take us to Three Mile Island, where our lessons on nucleare safety will be brought into a sharper focus.