The stability problem is a complex

The stability problem is a complex issue of power
system. The interconnected large-scale systems have become
an irreversible historical trend of electric power industry
development, coupled with frequent occurrence of stability
damage incidents of large-scale system [1-6], so that stability
problem becomes the focal point of much concern.
The complexity of electrical power safety problem not
only attributing to its high-dimensional, strong time-varying,
strong nonlinear characteristics and the differential–
difference-logic-algebra hybrid systems, but also reflected in
multi-field (physical, economic, information), many types of
stability(static, dynamic, transient, periodic, structure), multitime
scale (electromagnetic transient, electrical and
mechanical transient, medium, long-term), more physical
quantities (current, voltage, frequency, power angle) and
multi-spatial scales (local mode , the overall model) etc [7-9]. Thermal generation units are the main power production
equipments, but also the importance control components for
power system stability. Due to the power grid construction
and development, new problems caused by large-capacity
power generation equipments updated.
Low frequency oscillation is one of power system
dynamic stability problems [10], low frequency oscillation
have occured many times in actual power grid. Some experts
and scholars conduct a lot of useful studies [11-15], and give
forced resonance mechanism of low frequency oscillation,
that is, plus continuous disturbance forced power system to
forced oscillation. When the perturbation frequency is the
same as or close to power system natural oscillation
frequency, this resulted resonance and the power system
forced oscillations achieve maximum amplitude that
showing for dramatic swing in rotor angle between units,
transmission power sharp change in transmission lines.
Disturbance caused power system response, not only have
relation with the characteristics of the power system itself,
but also have relation with change law of the disturbance.
Simulation studies on multi-unit system and the actual
power grid have shown that the existence of low frequency
oscillation caused by a resonance mechanism in power
system. The interactions between thermal system and power
system are considered and the sources of resonance
mechanism low frequency oscillations in power system are
searched from thermal system [13, 15, 16]. The causes that
turbine pressure pulsation are analyzed and the type,
characteristics of the pressure pulsation are introduced, and
power system forced oscillation that causes by non-harmonic
cycle pulsation is explored in theory in [15,16]. Through
time-domain simulation in the multi-unit system, analysis the
impact of turbine complex pressure pulsation, quasi-periodic
pressure pulsation and the impact pressure pulsation on the
power system dynamic stability.
In this paper, taking dynamic simulation on low
frequency oscillation in power system as study background,
according to the characteristics of contemporary thermal
power equipment, through the custom modeling method [17-
18], and taking the unit mathematical model and its control
systems into the simulation environment, primary frequency,
boiler-turbine coordinated and power-frequency speed
governor control mechanism are taken into simulation
system to further explore the deep-seated reasons that causedthe turbine pressure pulsation