E F Johnson Company 2422001-1 Benutzerhandbuch
SERVICING
8-5
August 2000
Part No. 001-2001-200
Standby Battery Jack
This provides a connection point for a +24V DC
standby battery. Current is drawn from the battery
only when the repeater enable line is on and AC has
failed, or no AC is connected. A trickle charger can be
switched in to charge the battery when AC returns.
The charger switch is removed when a separate battery
charger is used (see Figure 8-4). The standby battery
connection to the power supply is factory or field
installable.
only when the repeater enable line is on and AC has
failed, or no AC is connected. A trickle charger can be
switched in to charge the battery when AC returns.
The charger switch is removed when a separate battery
charger is used (see Figure 8-4). The standby battery
connection to the power supply is factory or field
installable.
NOTE: A small amount (<30 mA) of current is drawn
from the batteries with the repeater off. If the repeater
is going to be turned off for more than one week (with
good batteries connected) the fuse should be removed
from the DC cable harness.
from the batteries with the repeater off. If the repeater
is going to be turned off for more than one week (with
good batteries connected) the fuse should be removed
from the DC cable harness.
8.5.1 VOLTAGE CHECKS
Secondary voltages can be checked at the power
supply connector with the power supply removed from
the Repeater. First the on/off line must be grounded,
jumper pin 5 to ground, then check the supply voltages
as shown (see Figure 8-3). If voltages are absent the
supply must be sent to the E.F. Johnson Company.
the Repeater. First the on/off line must be grounded,
jumper pin 5 to ground, then check the supply voltages
as shown (see Figure 8-3). If voltages are absent the
supply must be sent to the E.F. Johnson Company.
8.6 CHIP COMPONENT IDENTIFICATION
8.6.1 CERAMIC CHIP CAPACITORS (510-36XX-
XXX)
Ceramic chip capacitors are identified using
either an American or Japanese EIA standard. The
values for both standards are shown in Table 8-1.
values for both standards are shown in Table 8-1.
American EIA Standard
Uses a single letter or number to indicate the
value, and the color of this letter or number to indicate
the multiplier.
the multiplier.
Japanese EIA Standard
Uses a letter to indicate the value followed by a
number to indicate the multiplier.
Example: 15 pF capacitor
American - Single Black "E"
Japanese -"E1"
Japanese -"E1"
The Japanese EIA Standard may also utilize a bar
to indicate the temperature coefficient.
Example: A2 - 100 pF NPO
XX = NPO
XX = N150
XX = N220
XX = N330
XX = N470
XX = N750
|XX = X7R
8.6.2 TANTALUM CHIP CAPACITORS
(510-26XX-XXX)
Tantalum chip capacitor identification varies with
vendor and physical size. The positive (+) end is usu-
ally indicated by a colored board or beveled edge. The
value and voltage may be indicated by printing on the
capacitor or by using a special code.
ally indicated by a colored board or beveled edge. The
value and voltage may be indicated by printing on the
capacitor or by using a special code.
8.6.3 CHIP INDUCTORS (542-9000-XXX)
Three colored dots are used to indicate the value
of chip inductors. The two dots on the left side indi-
cate the first and second digits of the value in nano-
Henries, and the single dot on the right side indicates
the multiplier (see Table 8-2).
cate the first and second digits of the value in nano-
Henries, and the single dot on the right side indicates
the multiplier (see Table 8-2).
Example: Dots - Brown-Black-Red
10 nH x 100 = 1000 nH (1.0
µ
H)
The last three digits of the part number are also
the value and multiplier. The multiplier digits are
shown in Table 8-2.
shown in Table 8-2.
8.6.4 CHIP RESISTORS
The value of chip resistors is indicated by a num-
ber printed on the resistor. A 3-digit number is used to
identify
identify
±
5% and
±
10% resistors, and a 4-digit number
is used to identify
±
1% resistors.