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48
1Power Protection and Conditioning
The MCR provides excellent noise ltering and surge
protection to protect connected equipment from damage,
degradation or misoperation. Combined with the excellent
voltage regulation inherent to SolaHD’s ferroresonant design,
they can increase the actual Mean Time Between
Failure (MTBF) of protected equipment. These units are a
perfect choice where dirty power caused by impulses, swell,
sags, brownouts and waveform distortion can lead to costly
downtime because of damaged equipment.
Applications
Computers/ Printers
Telephone/FAX systems
POS terminals
Security systems
Laboratory equipment
LAN networks
Features
±3% output voltage regulation
Noise attenuation
- 120 dB common mode
- 60 dB transverse mode
Surge protection tested to ANSI/IEEE C62.41
Class A & B waveform (<10 V let-through typical)
Harmonic ltering
Galvanic isolation provides exceptional
circuit protection.
Point-of-use protection (cord & plug connected)
- Easy & Flexible Installation
25 year typical MTBF
No maintenance required
Certifications and Compliances
All Models
• RoHS Compliant
Listed
- UL 1012
Select Models
Listed (1500VA Units)
- UL 1012, CSA C22.2 No. 66
Certied (70VA-1kVA Units)
- CSA C22.2 No. 66
Related Products
DIN Rail AC UPS (SDU)
Off-Line UPS (S1K Mini-Tower)
Line-Interactive UPS (S3K Mini-Tower)
MCR Portable Series – Power Line Conditioning with Voltage Regulation
E47379
Selection Tables: Single Phase
Group A – MCR Portable Series, 60 Hz
VA Catalog
Number
Voltage
Input/Output
Height
in (mm)
Width
in (mm)
Depth
in (mm)
Ship Weight
lbs (kg)
Receptacle (No.)
Type (NEMA)
Plug
(NEMA)
70 63-13-070-6 120 6.00 (152.4) 7.00 (177.8) 9.00 (228.6) 18.0 (8.16) (4) 5-15R 5-15P
150 63-13-115-6 120 6.00 (152.4) 7.00 (177.8) 9.00 (228.6) 21.0 (9.53) (4) 5-15R 5-15P
250 63-13-125-6 120 6.00 (152.4) 7.00 (177.8) 9.00 (228.6) 26.0 (11.79) (4) 5-15R 5-15P
500 63-13-150-6 120 9.00 (228.6) 9.00 (228.6) 16.00 (406.4) 32.0 (14.51) (4) 5-15R 5-15P
750 63-13-175-6 120 9.00 (228.6) 9.00 (228.6) 16.00 (406.4) 64.0 (29.03) (4) 5-15R 5-15P
1000 63-13-210-6 120 9.00 (228.6) 9.00 (228.6) 16.00 (406.4) 69.0 (31.30) (4) 5-15R 5-15P
1500 63-13-215-6 120 11.00 (279.4) 11.00 (279.4) 17.00 (431.8) 95.0 (43.09) (6) 5-15R 5-20P
2000 63-13-220-6 120 11.00 (279.4) 11.00 (279.4) 17.00 (431.8) 115.0 (52.16) (4) 5-15R, (1) L5-30R L5-30P
3000 63-13-230-6 120 11.00 (279.4) 11.00 (279.4) 17.00 (431.8) 143.0 (64.86) (4) 5-15R, (1) L5-30R 5-50P
LR044950
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49
1
Power Protection and Conditioning
Plug & Receptacle Reference Chart
5-15R
5-15P L5-30P
Back Panels
60 Hz, 2000–3000 VA,
(4) 5-15R and (1)
L5-30R Receptacle
60 Hz, 70 – 1000 VA,
(4) 5-15R Receptacles
Specifications
Parameter Condition Value
Input
Voltage Continuous at full load (lower input voltage possible at lighter load) +10% to -20% of nominal
For temporary surge or sags +20% to -35% of nominal
Current 1At Full Load & 80% of nominal input voltage Iin (VA/.89)/(Vin x 80%)
Frequency See Operating Characteristics section for details. 60 Hz depending on model
Output 1
Line Regulation Vin >80% and <110% of nominal ± 3% for 60 Hz units
Overload Protection At Nominal Input Voltage Current limited at 1.65 times rated current
Output Harmonic Distortion At full load within input range 3% total RMS content
Noise Attenuation -Common Mode
-Transverse Mode
120 dB
60 dB
Let-Through ANSI/IEEE C62.41 Class A & B Waveform <10V typical
General
Efficiency At Full Load 92% Typical
Storage Temperature Humidity <95% non-condensing -20° to +85°C
Operating Temperature Humidity <95% non-condensing -20° to 40°C
Audible Noise Full Resistive Noise 35 dBA to 65 dBA
Warranty 10 + 2 year limited warranty
Notes:
1 - It is recommended that the unit run at a minimum of 40-50% load.
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50
1Power Protection and Conditioning
Model Comparison
BTU Output Chart for CVS and MCR Series
Note: Ratings are for a 40oC ambient temperature.
Description Hardwired CVS Hardwired MCR Portable MCR
VA Ratings 30 to 7500 VA 120 to 15000 VA 70 to 3000 VA
Input Voltage Range +10/-20% of nominal
Voltage Regulation ±1% for an input line variation of +10/-20%.
No loss of output for line loss of 3 msec.
±3% for an input line variation of +10/-20% (50 Hz hardwired units ±5%.)
No loss of output for complete line loss of 3 msec.
Overload Limits output current to 1.65 x rated current at nominal input.
Output Harmonic
Distortion 3% total RMS content at full load.
Noise Isolation 40 dB common and normal code. 120 dB common mode and 60 dB normal mode.
Surge Protection
Up to 6000 Volt surges are suppressed to a
let through of less than 1% per ANSI/IEEE
C62.41 Class A & B waveforms.
ANSI/IEEE C62.41 Class A & B 6000 waveforms are
suppressed to a let-through of less than 0.2%.
Efficiency Up to 92% at full load Up to 90% at full load
Operating
Temperature -20oC to 50oC -20oC to 40oC
Audible Noise 32 dB to 65 dB 35 dB to 65 dB 34 dB to 49 dB
Warranty 10 year limited warranty
VA Ratings 120 250 500 750 1000 1500 2000 3000 5000 7500 10000 15000
Total BTUs 136 225 280 444 519 686 1229 1331 2117 2407 3209 4813
Note: All values are typical and may vary based on VA ratings of actual units.
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51
1
Power Protection and Conditioning
Regulation
SolaHD’s CVS power conditioners will hold output voltages
to ±1.0% or less with input variations as great as ±15%
(115V ±15% or 120 V +10%/-20%). Units operated at less
than rated load will maintain approximately ±1% regulation
over a wider input line voltage variation. Output meets NEMA
voltage specications even when input voltage drops to 65%
of nominal. The output versus input voltage relationship for a
typical CVS is show in Figure A.
Figure A: Load Variation
Note: MCR line regulations: ±3% for 60 Hz; ±5% for 50 Hz.
The typical performances shown in Figure B indicate that
most of the residual changes take place near the lower
(95 V) and upper (130 V) ends of the input range. It is
possible to improve output regulation if line variations remain
within a restricted range near the center of the nameplate
range (for example, 100-120 V).
Figure B: Line Regulation
Normally, the output voltage will rise as the load is
decreased. Typical percentages for changes in resistive
load from full to zero load as shown below.
Input Characteristics
SolaHD power conditioners include a resonant circuit that
is energized whether or not it is serving load. The input
current at no load or light load may run 50% or more of the
full primary current. As a result, the temperature of the unit
may rise to substantially full-load level, even at light or no
load. Input power factor will average 90-100% at full load,
but may drop to about 75% at half load and 25% at no load.
In any case, the current is always leading. The input no load
watts are about 12.5% of the VA rating.
Frequency
Output voltage varies linearly with a change of frequency of
the input voltage. This change is about 1.5% of the
output voltage for each 1% change in input frequency and in
the same direction as the frequency change.
CVS Conditioner
Rating - VA
Increase in Output Voltage due to
Load Removal
30 3%
60 & 120 2%
250 & over 1%
Operating Characteristics of the CVS & MCR Series
Except as noted, all characteristics of SolaHD’s CVS products also apply to the MCR series.
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52
1Power Protection and Conditioning
A constant voltage regulator will protect both itself and its
load against damage from excessive fault currents. Fusing
of load currents may not be necessary. The actual value of
short-circuit current varies with the specic design and
rating. Units may be operated indenitely at short-circuit.
This characteristic protects the unit itself as well as the load
and load circuit being served. Typical overload
performance is shown in Figure D.
Motor Loads
Because of the fast response time of the SolaHD circuit, any
current-limiting characteristic must be taken into account
for transient overloads such as motor starting and solenoid
operation. In general, the SolaHD constant voltage regulator
must have a capacity nearly equal to the maximum demand
made on it, even for an instant. To determine the power
rating of the regulator, peak motor-starting current or
solenoid inrush current should be measured or power factor
correcting capacitors should be used to reduce the starting
VA of the load.
Response Time
An important advantage of SolaHD’s ferroresonant
transformer is its fast response time compared with other
types of AC regulators. Transient changes in supply voltage
are usually corrected within 1½ cycles or less; the output
voltage will not uctuate more than a few percent, even
during this interval.
Figure D: Overload Performance
Figure C: Power Factor
Power Factor
SolaHD power conditioners regulate any power factor load.
Output voltage is a function of load current and load power
factor (see Figure C). If lower voltage under lagging power
factor is objectionable, correction may be made with capaci-
tors at the load. “Median” value of output voltage will vary
from the nameplate rating if the load has a power
factor other than that for which the transformer was
designed. Load regulation will also be relatively greater as
the inductive load power factor is decreased (see Figure C).
However, the resulting median values of output voltage will
be regulated against supply line changes at any reasonable
load or load power factor.
Efficiency
The copper magnet wire and lamination material used in
SolaHD ferroresonant products are selected to achieve
efciencies of 90% or higher. Whether or not an external load
is being served, current will be drawn from the line whenever
the primary is energized, since the capacitor remains
connected in the circuit.
Overload and Short Circuits
When the load is increased beyond the regulator’s rated
value, a point is reached where the output voltage suddenly
collapses and will not regain its normal value until the load is
partially released. Under direct short circuit, the load current
is limited to approximately 150-200% of the rated full load
value and the input watts to less than 10% of normal.
Operating Characteristics of the CVS & MCR Series
Except as noted, all characteristics of SolaHD’s CVS products also apply to the MCR series.
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53
1
Power Protection and Conditioning
Temperature
SolaHD’s ferroresonant power conditioners are very stable
with respect to temperature. The change in output voltage
is only 0.025%/°C. Units are factory adjusted to +2%/-0%
of nominal, with full load and nominal input voltage. This
adjustment to the high side of nominal is to compensate for
the natural temperature drift of about 1% that takes place
during initial turn-on or warm-up. When the unit warms up to
operating temperature, the voltage typically falls about 1%.
At a stable operating temperature, the output voltage will
change slightly with varying ambient temperatures. This shift
is equal to approximately 1% for each 40°C of temperature
change. The normal maximum temperature rise of a SolaHD
power conditioner may fall anywhere in the range of 40°C
to 110°C depending on the type and rating. The nominal
design ambient range is between -20°C and +50°C (-20°C
to +40°C for 70 - 1000 VA, 60 Hz portable models).
External Magnetic Field
In almost all applications, this effect may be disregarded.The
exclusive SolaHD “wide outside leg” construction reduces
stray magnetic elds to a practical minimum. On critical
applications, care should be taken in orientation of the core
with respect to critical circuits to minimize the effect of the
eld.
Phase Shift
The phase difference which exists between input and
output voltages is in the range of 120 degrees to 140
degrees at full load. This phase difference varies with the
magnitude and power factor of the load, and to a lesser
extent, with changes in line voltage and load power factor.
Transient Protection
Ferroresonant power conditioners protect input transients
(caused by lightning and load switching) from damaging the
sensitive electronic load. A typical surge protective device
(SPD) tries to ‘clamp’ a transient by diverting it to ground.
A ferroresonant power conditioner “blocks” the transient.
This ‘blocking’ action is achieved by total physical separation
from input (primary) to output (secondary). Because of
this difference in operation, it is difcult to apply the same
specications to a ferroresonant power conditioner. Some
parallels can be made however.
One, is that under load, the let-through voltage of a
ferroresonant power conditioner (SPD refers to "clamping
voltage”) is less than 10 V above the point where the sine
wave would normally be at any given time. The ferroresonant
power conditioner is an ‘active tracking’ suppressor with
several advantages. The Ferro power conditioner will not
shunt the transient to the ground line as SPD devices
typically do. Shunting the transient to ground can cause the
disturbance to be transmitted to other sensitive loads within
a facility. This can pose serious problems with electronic
or microprocessor-based equipment, especially if there is
poor grounding within a facility. Other advantages provided
by ferroresonant power conditioners include noise ltering,
ltering of harmonic distortion and protection against voltage
uctuations such as sags or swells. These features are not
provided by standard surge protection devices but are often
misrepresented or misused by SPD manufacturers trying to
market their product as a “Do All” power quality device.
Operating Characteristics of the CVS & MCR Series
Except as noted, all characteristics of SolaHD’s CVS products also apply to the MCR series.