Technical
sciences/Electronics and radio electronics
Meshkov A.S., Susdorf D.V.
“Komsomolsk-na-Amure’s state technical university”,
“S.-Petersburg’s state polytechnic
university”, Russia
Improving of energy efficiency
factor of low power electric drives
Energy saving is the priority line of the technical
policy for all of the developed countries. An analysis of the structure of
energy losses shows that between production, distribution and consumption of
the electricity the consumption has the most significant part of missing energy
(it can reach 90%). An electric drive
is one of the biggest consumers of the electric power in the whole world. Of
course, mainly all the attention of many engineers is focused on the powerful
engines. However, these engines have a big amount of efficiency is about 95-99%
and that's difficult to raise it more. On the other, hand we have an electric
drive of low power. As a result of its massive using in construction tools,
medicine equipment and different home appliances small raising of its
efficiency is able to safe megawatts of energy. Besides, the efficiency of
these engines is 30-60%. So, it gives a big field of work to improve this
amount, particularly in the adjustable speed drive. So it's a big electric energy economy reserve.
Single-phase collector engines of low power with a
serial excitement is widespread in modern equipment. Main causes of this are soft
mechanical characteristics and high overload capacity at the moment, for the
most part, and determine the wide application of these motors.
To ensure optimum operation of electrified instruments
and household appliances in terms of energy needed synthesis of the control
law, which allows to obtain the required mechanical characteristics of the
electric power consumption and optimize the work cycle.
Optimal control problem in terms of electric energy
successfully realizes future can be formulated as follows: change the speed of
the engine from the values v1 to v2, so that would be for any time of the
transient energy consumed by the transducer, was minimal. The basic equation of motion in the EP
system of relative units is as follows:
To ensure maximum dynamic efficiency:
where - is a loss in the EP: electrical and mechanical.
Necessary to satisfy the following conditions:
In cases where a function of speed and does not depend explicitly on time and way, the minimum of the definite integral is achieved, provided that for each value of the velocity on the time interval of the motor provides a minimum of the integrand:
Then, at a constant speed and neglecting mechanical
losses, the solution has the form:
Thus, the effective value of the supply voltage must
increase to a parabolic law. This function changes the current value of the supply voltage will be
optimal in terms of energy performance criteria.
To solve the problem of stabilizing the rate, as well as an indirect control of
dynamic torque is proposed to use the structure, forming a feedback signal as a
function inversely depending on engine speed. To do this, measure the
time decay of the self-induction EMF output to zero. This time with a high
degree of accuracy is proportional to the armature current and inversely
proportional to engine speed. The advantage of this
method is the ability to take into account the large number of perturbations,
including the heating of the motor, changing the voltage.
The time constant of the motor is given by:
From the presented equations can be seen that to
maintain a stable engine speed to maintain a constant decay time of self-induction
EMF to zero. This is done by regulating the width of the pulse voltage.
Conclusions:
- the optimal law of variation of the input voltage of
the electric motor, according
to the criterion of minimum loss, is its quadratic dependence on the electromagnetic torque;
- with variable torque load on the shaft of the single-phase
commutator motor is advisable to use the concept of dynamic efficiency of the proposed
control method and the structure of the electric drive can improve the dynamic efficiency
by up to 20%, while improving the quality of the spectrum of current that
affects the external current network, more than 3%.
Publications:
1. Krause P.C.,
Analysis of electric machinery and drive systems / Krause P.C., Wasynczuk O.,
Sudhoff S.D., - IEEE Press 2002, ñ. 76-84.
2. Áàðêîâ
Â.À. Ïîëóïðîâîäíèêîâûå
óñòðîéñòâà äëÿ óïðàâëåíèÿ ýëåêòðè÷åñêèìè ìàøèíàìè ïîñòîÿííîãî òîêà / Ó÷åáíîå
ïîñîáèå, Ëåíèíãðàä, 1982.