Read Zero Hour: A Post-Apocalyptic EMP Survival Fiction Series (The Blackout Series Book 2) Online
Authors: Bobby Akart
Depending on the explosive yield of the nuclear weapon used, EMP-induced GIC may be several times larger than that produced by the average geomagnetic storm, and may even be comparable to those expected to arise in the largest geomagnetic storm ever observed. It may also occur over an area not normally affected by historic geomagnetic storms.
The North American economy and the functioning of the society as a whole are critically dependent on the availability of electricity, as needed, where and when needed. The electric power system in the US and interconnected areas of Canada and Mexico is outstanding in terms of its ability to meet load demands with high quality and reliable electricity at reasonable cost. However, over the last decade or two, there has been relatively little large-capacity electric transmission constructed and the generation additions that have been made, while barely adequate, have been increasingly located considerable distances from load for environmental, political, and economic reasons. As a result, the existing National electrical system not infrequently operates at or very near local limits on its physical capacity to move power from generation to load. Therefore, the slightest insult or upset to the system can cause functional collapse affecting significant numbers of people, businesses, and manufacturing. It is not surprising that a single EMP attack may well encompass and degrade at least 70% of the Nation’s electrical service, all in one instant.
The impact of such EMP is different and far more catastrophic than that effected by historic blackouts, in three primary respects:
1. The EMP impact is virtually instantaneous and occurs simultaneously over a much larger geographic area. Generally, there are neither precursors nor warning, and no opportunity for human-initiated protective action. The early-time EMP component is the “electromagnetic shock” that disrupts or damages electronics-based control systems and sensors, communication systems, protective systems, and control computers, all of which are used to control and bring electricity from generation sites to customer loads in the quantity and quality needed. The E1 pulse also causes some insulator flashovers in the lower-voltage electricity distribution systems (those found in suburban neighborhoods, in rural areas and inside cities), resulting in immediate broad-scale loss-of-load. Functional collapse of the power system is almost definite over the entire affected region, and may cascade into adjacent geographic areas.
2. The middle-time EMP component is similar to lightning in its time-dependence but is far more widespread in its character although of lower amplitude—essentially a great many lightning-type insults over a large geographic area which might obviate protection. The late-time EMP component couples very efficiently to long electrical transmission lines and forces large direct electrical currents to flow in them, although they are designed to carry only alternating currents. The energy levels thereby concentrated at the ends of these long lines can become large enough to damage major electrical power system components. The most significant risk is synergistic, because the middle and late-time pulses follow after the early-time pulse, which can impair or destroy protective and control features of the power grid. Then the energies associated with the middle and late-time EMP thus may pass into major system components and damage them. It may also pass electrical surges or fault currents into the loads connected to the system, creating damage in national assets that are not normally considered part of the infrastructure per se. Net result is recovery times of months to years, instead of days to weeks.
3. Proper functioning of the electrical power system requires communication systems, financial systems, transportation systems, and—for much of the generation—continuous or nearly continuous supply of various fuels. However, the fuel-supply, communications, transportation, and financial infrastructures would be simultaneously disabled or degraded in an EMP attack and are dependent upon electricity for proper functioning. For electrical system recovery and restoration of service, the availability of these other infrastructures is essential. The longer the outage, the more problematic, and uncertainty-fraught the recovery will be.
The recent cascading outage of August 14, 2003, is an example of a single failure compounded by system weaknesses and human mistakes. It also provides an example of the effectiveness of protective equipment. However, with EMP there are multiple insults coupled with the disabling of protective devices simultaneously over an extremely broad region—damage to the system is likely and recovery slow.
RECOMMENDED MITIGATION AND RESPONSIBILITY
The electrical system is designed to break into “islands” of roughly matching generation and load when a portion of the system receives a severe electrical insult. This serves both to protect electricity supply in the non-impacted regions and to allow for the stable island-systems to be used to “restart” the island(s) that have lost functionality. With EMP, the magnitude, speed, and multi-faceted nature of the insult, its broad geographic reach, along with the number of simultaneous insults, and the adverse synergies all are likely to result in a situation where the islanding scheme will fail to perform as effectively as intended, if at all. Since the impacted geographic area is large, restoring the system from the still-functioning perimeter regions would take a great deal of time, possibly weeks to months at best. Indeed, the only practical way to restart much of the impacted electrical system may be with generation that can be started without an external power source. This is called “black start” generation and primarily includes hydroelectric (including pumped storage), geothermal, and independent diesel generators of modest capacity.
The recommended actions will substantially improve service and recovery during “normal” large-scale blackouts, and will critically enable recovery under EMP circumstances.
PROTECTION
It is impractical to protect the entire electrical power system from damage by an EMP attack. There are too many components of too many different types, manufacturers, designs, and vulnerabilities within too many jurisdictional entities, and the cost to retrofit is too great. Widespread functional collapse of the electrical power system in the area affected by EMP is possible in the face of a geographically broad EMP attack, with even a relatively few unprotected components in place. However, it is practical to reduce to low levels the probability of widespread damage to major power system components that require long times to replace. This will enable significantly improved recovery times, since it avoids the loss of long lead-time and critical components. It is important to protect the ability of the system to fragment gracefully into islands, to the extent practical in the particular EMP circumstance. This approach is cost-efficient and can leverage efforts to improve reliability of bulk electricity supply and enhance its security against the broader range of threats.
RESTORATION
The key to minimizing adverse effects from loss of electrical power is the speed of restoration. Restoration involves matching generation capacity to a load of equivalent size over a transmission network that is initially isolated from the broader system. The larger system is then functionally rebuilt by bringing that mini system, or “island,” to the standard operating frequency and thereupon by adding more blocks of generation and load to this core in amounts that can be absorbed by the growing subsystem. This is a demanding and time-consuming process in the best of circumstances. In the singular circumstance of an EMP attack with multiple damaged components, related infrastructure failures, and particularly severe challenges in communications and transportation, the time required to restore electrical power is expected to be considerably longer than we have experienced in recent history.
However, by protecting key system components needed for restoration, by structuring the network to fail gracefully, and by creating a comprehensive prioritized recovery plan for the most critical power needs, the risk of an EMP attack having a catastrophic effect on the Nation can be greatly reduced. DHS must ensure that the mitigation plan is jointly developed by the federal government and the electric power industry, implemented fully, instilled into systems operations, and tested and practiced regularly to maintain a capability to respond effectively in emergencies. The North American Reliability Council and the Electric Power Research Institute are aptly positioned to provide much of what’s needed to support DHS in carrying out its responsibilities. The US Energy Association is well-suited to coordinating activities between and among the various energy sectors that together affect the electric power system and its vitality.
ESSENTIAL COMPONENT PROTECTION
1. Assure protection of high-value long-lead-time transmission assets.
2. Assure protection of high-value generation assets. System-level protection assurance is more complex due to the need for multiple systems to function in proper sequence.
3. Assure Key Generation Capability. Not all plants can or should be protected. However, regional evaluation of key generating resources necessary for recovery should be selected and protected.
a. Coal-fired generation plants make up nearly half the Nation’s generation and are generally the most robust overall to EMP, with many electromechanical controls still in operation. Such coal plants also normally have at least a few days to a month of on-site fuel storage.
b. Natural gas-fired combustion turbines and associated steam secondary systems represent the newest and a significant contributor to meeting loads. These have modern electronics-based control and thus are more vulnerable. Natural gas is not stored on-site and likely will be interrupted in an EMP attack. However, provision can be made to have gas-fired plants also operate on fuel oil; many do already.
c. Nuclear plants produce roughly 20% of the Nation’s generation and have many redundant fail-safe systems that tend to remove them from service whenever any system upset is sensed. Their safe shut down should be assured, but they will be unavailable until near the end of restoration.
d. Hydroelectric power is generally quite robust to EMP, and constitutes a substantial fraction of total national generation capacity, albeit unevenly distributed geographically.
e. In general, the various distributed and renewable fueled generators are not significant enough at this time to warrant special protection.
f. Black start generation of all types is critical and will need to be protected from EMP upset or damage.
4. Assure functional integrity of critical communications channels. The most critical communications channels in the power grid are the ones that enable recovery from collapse, such as ones that enable manual operation and coordination-supporting contacts between distant system operators and those that support system diagnostics. Generation, switching, and load dispatch communications support is next in importance.
5. Assure availability of emergency power at critical facilities needed for restoration. Transmission substations need uninterruptible power to support rapid restoration of grid connectivity and operability, and thereby to more quickly restore service. Most have short-life battery backup systems, but relatively few have longer-duration emergency generators; much more emphasis on the latter is needed.
6. Assure protection of fuel production and its delivery for generation. Fuel supply adequate to maintain critical electrical service and to restore expanded service is critical.
7. Expand and assure intelligent islanding capability. The ability of the larger electrical power system to break into relatively small subsystem islands is important to mitigate overall EMP impacts and provide faster restoration.
8. Develop and deploy system test standards and equipment. Device-level robustness standards and test equipment exist, but protection at the system level is the overarching goal. System-level robustness improvements such as isolators, line protection, and grounding improvements will be the most practical and least expensive in most cases relative to replacement with more robust individual component devices. Periodic testing of system response is necessary.
SYSTEM RESTORATION
1. Develop and enable a restoration plan. This plan must prioritize the rapid restoration of power to government-identified critical service. Sufficient black start generation capacity must be provided where it is needed in the associated subsystem islands, along with transmission system paths that can be isolated and connected to matching loads. The plan must address outages with wide geographic coverage, multiple major component failures, poor communication capabilities, and widespread failure of islanding schemes within the EMP-affected area. Government and industry responsibilities must be unequivocally and completely assigned. All necessary legal and financial arrangements, e.g., for indemnification, must be put into place to allow industry to implement specified government priorities with respect to service restoration, as well as to deal with potential environmental and technical hazards in order to assure rapid recovery.
2. Simulate, train, exercise, and test the plan. Simulators must be developed for use in training and developing procedures similar to those in the airline industry; a handful should suffice for the entire country. Along with simulation and field exercises, Red Team discipline should be employed to surface weaknesses and prioritize their rectification.
3. Assure sufficient numbers of adequately trained recovery personnel.
4. Assure availability of replacement equipment. R&D is under way—and should be vigorously pursued—into the production of emergency “universal” replacements. The emergency nature of such devices would trade efficiency and service-life for modularity, transportability, and affordability.
5. Implement redundant backup diagnostics and communication. Assure that system operators can reliably identify and locate damaged components.
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