18-01-2013, 02:29 PM
CHOOSING MEDICAL POWER SUPPLIES
CHOOSING MEDICAL POWER SUPPLIES.pdf (Size: 473.21 KB / Downloads: 56)
Most electronic design engineers working in the medical equipment sector will have a strong familiarity with the
provisions of IEC 60601-1. The standard defines the general safety requirements for equipment that has ‘not more than
one connection to a particular supply mains and is intended to diagnose, treat, or monitor the patient under medical
supervision and which makes physical or electrical contact with the patient’. IEC 60601-1 has been adopted by the UK
and Europe as EN 60601-1, as well as most major industrialized countries, including the US (UL 60601-1), Canada (C22.2
No. 601.1), Japan (JIS T0601-1), Australia and New Zealand (AS/NZ 3200.1).
The 60601-1 safety standard applies to a diverse range of equipment intended for use in medical, dental and laboratory
environments. Examples range from small items of equipment such as thermometers, infusion pump controls and
endoscopic cameras, through to larger systems such as dialysis machines, MRI scanners and gamma imaging systems.
Designing-in Power
Choosing or designing an ac-dc power supply for a medical product involves all the usual considerations, such
as overall power budget, current and voltage requirements, conversion efficiency, physical size, control and
monitoring functions, set-up or programmable features, and, of course, cost. On top of this comes the need to
secure a power supply that has lower safety ground leakage and higher isolation than a standard non-medical unit,
in order to comply with the 60601-1 safety standard.
Given that designing modern high-efficiency switch-mode power supplies is a craft in itself, and that medical
equipment has to undergo strict compliance testing, most designers nowadays elect to use standard commercially
available medical power supplies, or seek the help of a specialist power supply company to create a customized
unit. Using power supplies that are already pre-approved to the 60601-1 safety standard helps medical equipment
manufacturers speed compliance testing of their own products, and minimizes the risk of them encountering
unexpected development problems outside their own area of expertise, which might negatively impact launch
targets.
Worldwide, there is a considerable number of medical power supply manufacturers to choose from, many of
which produce excellent products. One of the leading companies is Emerson Network Power, which is responsible
for the well-known Astec and Artesyn brands. Together, these two product brands encompass literally thousands
of ac-dc power supplies and dc-dc converters, many of which are available
in 60601-1 compliant versions. Emerson Network Power supplies medically
approved standard and custom ac-dc power supplies covering a 40 to 4,860
watt power band, to many of the world’s most prestigious medical equipment
manufacturers. The NLP250 series is a typical example: these high power density
open-frame 250 watt ac-dc power supplies offer a choice of ten models, four of
which are medically approved versions.
So, given this wide availability of 60601-1 compliant power supplies, surely it’s simply a matter of choosing a product
to suite the particular needs of the application, and then sitting back and basking in the glow of yet another design
success? Well, not quite. IEC 60601-1 is a classic example of what is known as a base standard; it covers all the
general requirements for electrical medical equipment, but it also has a number of associated standards, known as
collateral standards. One of these is IEC 60601-1-2, which defines the rigorous electromagnetic compatibility (EMC)
requirements of medical power supplies.
Obviously, all IEC 60601-1 compliant power supplies meet the EMC requirements of IEC 60601-1-2, otherwise they
wouldn’t be approved. And these requirements became a mandatory condition of sale back in 2004. But meeting
the voltage dip requirements of IEC 60601-1-2 – which are themselves the subject of a further complementary pair
of IEC standards known as 61000-4-11 and 61000-4-34 – is a matter of some controversy.
Both IEC 61000-4-11 and IEC 61000-4-34 define how equipment must be capable of tolerating voltage dips, voltage
variations and short power interrupts on the ac mains supply. The standards specify the same depths and durations
of voltage dips, and cover both single-phase and three-phase equipment. IEC 61000-4-11 applies to equipment
rated at up to 16 amps per phase connected to 50 Hz or 60 Hz ac supply networks, whereas IEC 61000-4-34 applies
to equipment rated higher than 16 amps per phase. For the purpose of discussion, we’ll confine our attention to the
lower power standard.
The problem is that deciding whether or not a piece of medical equipment meets the requirements of IEC 61000-4-
is open to interpretation. Broadly speaking, the standard stipulates that the equipment should not suffer ‘loss of
functionality’ for a 30% dip in supply voltage lasting 0.5 s, a 60% dip lasting 100 ms, and a 100% dip lasting 10 ms.
It should also not suffer ‘loss of functionality’ in the event of ac power being removed altogether for a period of 5
seconds. However, ‘loss of functionality’ is to some degree subjective, and the compliance test procedure recognizes
this fact by defining four distinct classification levels, as shown in Table 1.
Embedded Power for
Business
Critical Continuity™
A Matter of Standards
NLP250 Medical Power Supply
Provided that the equipment is not intended for critical life support functions, the choice of which classification category
to adopt for compliance testing is left to the discretion of the equipment designer. It is also up to the designer to decide
what constitutes full functionality – and therefore by definition, what also constitutes ‘loss of functionality’. This is
inevitably something of a grey area. Most standard low to medium power open-frame medical power supplies, which
represent by far the largest segment of the market, are too small and inexpensive to satisfy classification A – achieving
lengthy hold-up times at full load with absolutely no degradation in voltage regulation demands the addition of
significant holdup capacitance or larger input components for lower voltage operation. To help designers decide which
classification to use for compliance testing their equipment, Emerson Network Power is in the process of adding detailed
EMC characterisation data to its Product Application Notes.