Electric clocks The reasonably constant frequency of the electric power grid is used by some
electric clocks to accurately maintain their time. In practice, the exact frequency of the grid varies around the nominal frequency, reducing when the grid is heavily loaded, and speeding up when lightly loaded. However, most utilities will adjust generation onto the grid over the course of the day to ensure a constant number of cycles occur.
Time error correction (TEC) Regulation of power system frequency for timekeeping accuracy was not commonplace until after 1916 with
Henry Warren's invention of the
Warren Power Station Master Clock and self-starting synchronous motor.
Nikola Tesla demonstrated the concept of clocks synchronized by line frequency at the
1893 Chicago Worlds fair. The
Hammond Organ also depends on a synchronous AC clock motor to maintain the correct speed of its internal "tone wheel" generator, thus keeping all notes pitch-perfect. Today, AC power network operators regulate the daily average frequency so that clocks stay within a few seconds of the correct time. In practice the nominal frequency is raised or lowered by a specific percentage to maintain synchronization. Over the course of a day, the average frequency is maintained at a nominal value within a few hundred parts per million. In the
synchronous grid of Continental Europe, the deviation between network phase time and
UTC (based on
International Atomic Time) is calculated at 08:00 each day in a control center in
Switzerland. The target frequency is then adjusted by up to ±0.01 Hz (±0.02%) from 50 Hz as needed, to ensure a long-term frequency average of exactly 50 Hz × 60
s/
min × 60 min/
h × 24 h/
d = cycles per day. In
North America, whenever the error exceeds 10 seconds for the
Eastern Interconnection, 3 seconds for the
Texas Interconnection, or 2 seconds for the
Western Interconnection, a correction of ±0.02 Hz (0.033%) is applied. Time error corrections start and end either on the hour or on the half-hour. Real-time frequency meters for power generation in the United Kingdom are available online – an official one for the National Grid, and an unofficial one maintained by Dynamic Demand. Real-time frequency data of the synchronous grid of Continental Europe is available on websites such as . The
Frequency Monitoring Network (FNET) at the
University of Tennessee measures the frequency of the interconnections within the North American power grid, as well as in several other parts of the world. These measurements are displayed on the FNET website.
US regulations In the United States, the
Federal Energy Regulatory Commission made time error correction mandatory in 2009. In 2011, The
North American Electric Reliability Corporation (NERC) discussed a proposed experiment that would relax frequency regulation requirements for electrical grids which would reduce the long-term accuracy of clocks and other devices that use the 60 Hz grid frequency as a time base.
Frequency and load Modern alternating-current grids use precise frequency control as an
out-of-band signal to coordinate generators connected the network. The practice arose because the frequency of a mechanical
generator varies with the input
force and output
load experienced. Excess load withdraws
rotational energy from the generator shaft, reducing the
frequency of the generated current; excess force deposits rotational energy, increasing frequency.
Automatic generation control (AGC) maintains scheduled frequency and interchange power flows by adjusting the generator
governor to counteract frequency changes, typically within several
decaseconds.
Flywheel physics does not apply to
inverter-connected
solar farms or other
DC-linked power supplies. However, such
power plants or storage systems can be
programmed to follow the frequency signal. Indeed, a 2017 trial for
CAISO discovered that solar plants could respond to the signal faster than traditional generators, because they did not need to
accelerate a rotating mass. Small, temporary frequency changes are an unavoidable consequence of changing demand, but dramatic, rapid frequency shifts often signal that a distribution network is near capacity limits. Exceptional examples have occurred before major
outages. During a severe failure of generators or transmission lines, the ensuing load-generation imbalance will induce variation in local power system frequencies. Loss of an
interconnection causes system frequency to increase (due to excess generation) upstream of the loss, but may cause a collapse in frequency or
voltage (due to excess load) downstream of the loss. Consequently many power system
protective relays automatically trigger on severe underfrequency (typically too low, depending on the system's disturbance tolerance and the severity of protection measures). These initiate
load shedding or
trip interconnection lines to
preserve the operation of at least part of the network. Smaller power systems, not extensively interconnected with many generators and loads, will not maintain frequency with the same degree of accuracy. Where system frequency is not tightly regulated during heavy load periods, system operators may allow system frequency to rise during periods of light load to maintain a daily average frequency of acceptable accuracy. Portable generators, not connected to a utility system, need not tightly regulate their frequency because typical loads are insensitive to small frequency deviations.
Load-frequency control Load-frequency control (LFC) is a type of
integral control that restores the system frequency while respecting
contracts for power provision or consumption to surrounding areas. The automatic generation scheme described in establishes a
damping that minimizes the magnitude of average frequency error, , where is frequency, refers to the difference between measured and desired values, and
overlines indicate time averages. LFC incorporates power transfer between different areas, known as "net
tie-line power", into the minimized quantity. For a particular
frequency bias constant , the
area control error (ACE) associated with LFC at any moment in time is simply \Delta(P_T-Bf)\text{,} where refers to tie-line power. This instantaneous error is then
numerically integrated to give the time
average, and governors adjusted to counteract its value. The coefficient traditionally has a negative value, so that when the frequency is lower than the target, area power production should increase; its magnitude is usually
on the order of MW/
dHz. Tie-line bias LFC was known since 1930s, but was rarely used until the
post-war period. In the 1950s,
Nathan Cohn popularized the practice in a series of articles, arguing that load-frequency control minimized the adjustment necessary for changes in load. In particular, Cohn supposed that all regions of the grid shared a common
linear regime, with location-invariant frequency change per additional loading (). If the utility selected B=\frac{1}{2}\frac{dL}{df}\text{,} and one region experienced a temporary
fault or other generation-load mismatch, then adjacent generators would observe a decrease in frequency but a counterbalancing increase in outward tieline power flow, giving no ACE. They would thus make no governor adjustments in the (presumed) brief period before the failed region recovered.
Rate of change of frequency Rate of change of frequency (also
ROCOF) is simply a time
derivative of the utility frequency ({df}/{dt}), usually measured in Hz per second, Hz/s. The importance of this parameter increases when the traditional
synchronous generators are replaced by the
variable renewable energy (VRE)
inverter-based resources (IBR). The design of a synchronous generator inherently provides the
inertial response that limits the ROCOF. Since the IBRs are not electromechanically coupled into the power grid, a system with high VRE penetration might exhibit large ROCOF values that can cause problems with the operation of the system due to stress placed onto the remaining synchronous generators, triggering of the protection devices and
load shedding. Using ROCOF to distinguish between harmless noise and dangerous excursions is also difficult, and may cause false disconnects. Whereas some
HVDC terminals are required to remain grid-tied up to a ROCOF of 2.5 Hz/s, wind turbines may remain stable up to 4 Hz/s. As of 2017, regulations for some grids required the power plants to tolerate ROCOF of 1–4 Hz/s, the upper limit being a very high value, an order of magnitude higher than the design target of a typical older gas turbine generator. Testing high-power (multiple
MW) equipment for ROCOF tolerance is hard, as a typical test setup is powered off the grid, and the frequency thus cannot be arbitrarily varied. In the US, the
controllable grid interface at the
National Renewable Energy Laboratory is the only facility that allows testing of multi-MW units (up to 7
MVA). Testing of large thermal units is not possible. ==Audible noise and interference==