SPARK QUENCHERS

SPARK QUENCHERS
Spark Quenchers are easily selectable electronic
components designed to prevent or substantially
minimize the occurrence of arcing and noise
generation in relay and switch contacts.
Spark Quenchers consist of specially designed
capacitors and resistors connected in series. Spark
discharges and induced noise are absorbed over a
wide range by the accumulation characteristic and
impedance of the capacitor, while the RC time
constant delays and averages surge voltage and
oscillations.
EFFECT OF SPARK QUENCHER
Arc suppression
Damping oscillation
At the moment of switch opening, the RC
combination absorbs and suppresses the energy of
the arc by letting it bypass the switch.
The RC combination absorbs the high frequency
oscillations caused by mechanical vibrations such as
relay contact chattering. Similarly the oscillations
created by arcing are also averaged and suppressed
by the RC combination regardless of their origin.
Back electromotive force suppression
Dv/dt suppression
With back electromotive force due to
self-inductance, the surge voltage peak is suppressed
by conducting it through the RC circuit on the low
impedance side. The peak is absorbed by the
capacitance of RC. The wave-form is averaged and
smoothed by the time constant of the RC; thus
generated noise is eliminated or substantially
minimized.
The RC combination allows the dv/dt of the "on"
and "off" operation of thyristors or similar devices to
decrease; thus surge voltages are suppressed and
semi-conductor elements are protected.
Even in the case of zero crossing circuits, such as
AC circuits, protection is necessary since harmonic
noise occurs when there is a gap between phases or
current and voltage of the load circuit.
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SPARK QUENCHERS
OKAYA Spark Quenchers have the following
characteristics which make it possible to easily use
them in a wide range of applications.
1) The Overload capacity is large.
2) They are not polarized; thus can be used in both
AC an DC circuits.
3) They have a favorable effect on surge voltage and
accompanying oscillations caused by contact
chatter.
4) They are effective against spurious potentials
having magnitudes below circuit voltage.
5) They offer a high degree of protection for
semiconductor devices, and as thyristors and
SCRs.
6) They improve the dv/dt ratio.
OUTLINE OF CAPACITOR CLASS RATINGS
Capacitors are classified by the IEC into the
following categories (these designations are used by
most European countries) :
Class Y: Capacitors used in applications where
damage to the capacitor may involve the
danger of electrical shock.
Class X: Capacitors used in applications where
damage to the capacitor will not lead to the
danger of electrical shock.
European Safety Agencies subdivide Class X into
X1, X2 and X3 classifications. The test criteria for
these subclasses is shown in the table.
Subclass
Peak Voltage
on Service
Peak Voltage Test
1.2/50 sec.
X1
X2
X3
>2,500V ”4,000V
”2,500V
”1,200V
4,000V
2,500V
None
RC COMBINATION TABLE
0.01
0.033
0.1
0.2
10
27
33
XE
XEB
XE
XEB
XE
XEB
AU
XE
XEB
AU
XE
XEB
AU
XE
XEB
AU
100
XE
XEB
CRE
3CRE
CRH
3CRH
CRH
XE
XEB
CRH
3CRH
XE
XEB
XE
120
150
XE
XEB
RE
XE
XEB
AU
RE
XE
XEB
AU
RE
XE
XEB
RE
CRH
XE
XEB
0.47
1.0
68
XE
XEB
0.33
0.5
50
XE
XEB
0.22
0.3
47
CRE
3CRE
6CRE
XE
XEB
53
160
200
CRE
220
470
XE
XEB
XE
XEB
XE
XEB
XE
XEB
XE
XEB
XE
XEB
XE
XEB
CRE
XE
XEB
500
SPARK QUENCHERS
μF
SPARK QUENCHERS
GENERAL CONSTRUCTION
SAFETY STANDARDS
Spark Quenchers must have the capacity to store
surge voltages and current energy, and afford
protection against inductively induced potentials.
The dielectric material of the OKAYA capacitors,
used in Spark Quenchers, affords a very high
degree of voltage withstand strength. All resistors
are non-inductive solid slug type to insure a high
degree of protection against pulse potentials. To
provide additional protection for equipment and
users, especially when these components are used
in AC applications, all OKAYA Spark Quenchers are
packaged in cases which meet UL-94 Flame Class
V-O.
Safety standards for capacitors used in con-junction
with AC power sources have recently been adopted
by many world wide standards agencies.
OKAYA Spark Quenchers are fully tested to these
standards (see Chart). As well, Okaya is able to offer
some products with 500 Vac ratings.
APPLICATIONS
A) Protection for contacts and from noise during
switching operations of equipment such as radio,
TV, copiers, mixers, coffee grinders, dryers, tool
machine equipment, etc.
B) Protection of electronic instruments during
operation of relays, solenoids, motors, etc.
C) Electrical noise protection of semiconductor
devices during control of triacs, thyristors, motors,
welders, illumination equipment, etc.
FORM
Line Voltage
250Vac
250Vac
275Vac*
250Vac
250Vac
250Vac
250Vac
250Vac
500Vac
500Vac
Safety Standard
Lead Type
Bare wire
Bare wire
Bare wire
Bare wire
Flex PVC wire
Flex PVC wire
Flex PVC wire
Flex PVC wire
Flex PVC wire
Flex PVC wire
10
(30680 : not approved)
Forms
a
a
a
a
b
d
e
g
c
f
Model
AU series
TA series
RE series
XE series
XEB series
CRE series
3CRE series (3 phase delta connection)
6CRE series (3 individual circuits)
CRH series
3CRH series (3 phase delta connection)
* UL and CSA = 250Vac
a.
b.
c.
d.
e.
f.
APPLICATIONS
Standard example in DC circuits.
Standard example in AC circuits.
For phase control circuits
employing SCR or TRIAC, etc.
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g.
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SPARK QUENCHERS
DESIGN CAUTIONS
EXPRESSION OF RATED VOLTAGE
1) Using OKAYA Spark Quenchers will help prevent
abnormal operation due to electrical noise and/or
surge pulses. It is not recommended that these
devices be used in circuits with frequencies greater
than 70 Hz. When used in 3-phase, full wave
rectified applications, care must be taken to insure
that the Spark Quencher does not self heat by
more than 5 degrees centigrade or permanent
damage to the Spark Quencher may occur.
2) When protecting contacts feeding small circuit
loads, it is recommended that the Spark Quencher
be placed in parallel with the load, rather than the
contacts, for the most effective application.
3) In high speed circuits, the addition of a Spark
Quencher may slow the response time of the
circuit. For best response characteristics, do not
use a larger Spark Quencher than is absolutely
necessary to suppress the noise level.
4) Spark Quenchers should be connected as close as
possible to the noise source. Excessive lead length
may allow abnormal oscillation and/or decrease
energy absorption capacity.
5) When a thyristor, triac or invertor circuit is to be
protected by a Spark Quencher, care must be
taken that high harmonic currents do not cause
over heating of the Spark Quencher resistor. If
heating occurs, we suggest the employment of a
Spark Quencher with a lower resistance. The Spark
Quencher must not self heat by more than 5
degrees centigrade. In invertor applications, it is
recommended that an OKAYA noise suppression
capacitor be used across the power lines, instead
of the Spark Quencher.
6) While it may appear effective to protect contacts
with a capacitor only, the capacitor discharge
current will cause accumulative damage to the
contacts when they close. The proper technique is
to apply a Spark Quencher across either the
contacts or the load.
7) Regarding the pulse condition (superimposed pulse
condition), value of ( ) shows the condition of rated
voltage. Please careful not to raise the temperature
rise when use in the phase control circuit.
8) Peak to peak value of pulse condition shows the
maximum pulse voltage that is able to apply
between terminals of spark quencher with
superimposed line voltage. It must not exceed the
peak pulse voltage when add the line voltage.
The rated voltage of OKAYA Spark Quenchers is
expressed by the steady-state (line) voltage rating.
They can, however, withstand much higher voltages
from power surges. In this catalog, the maximum
voltage (including the line voltage) that the Spark
Quenchers can withstand is expressed as the "Peak
Pulse Voltage". For example, the XE series is rated
250Vac RMS (350Vac Peak) maximum line voltage,
but can withstand surge voltages up to 1,200Vac
(including Peak line voltage). "Pulse Condition"
means the maximum voltage that can be input
between terminals of the Spark Quencher (excluding
line voltage) during operation. For example, when the
XE series is used in a 250Vac RMS (350Vac Peak)
line voltage application, it can withstand surge
voltages up to 800Vac (P-P) above the Peak line
voltage. The following drawing shows examples of
both "Peak Pulse Voltage" and "Pulse Condition" for
clarification.
"Pulse Condition"
1,200
**
1,000
*
800
600
*
*
SPARK QUENCHERS
400
*
200
0
-200
*
-400
*
-600
-800
-1,000
* Pulse Condition (Surge pulse p.p.)
** Peak Pulse Voltage (Peak line voltage plus surge pulse)
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SPARK QUENCHERS
PERFORMANCE CHARACTERISTICS
Temperature Endurance
Damp Heat Endurance
Temperature Characteristics
TEST CONDITIONS
Temperature Endurance:
While operating at maximum rated
temperature and at 125% of rated
voltage, input the table voltages four
times per hour for 0.1 second.
Model
AU, CRE
XE
CRH
Damp Heat Endurance:
60°C, 90~95% RH
100% Rated Voltage
Applied voltage
880 Vac
1,000 Vac
1,500 Vac
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Temperature Characteristics:
-50°C to ~100°C
100% Rated Voltage