Abt Powerline SC12-12 Ürün Kılavuzu - Sayfa 10

Kamera Aksesuarları Abt Powerline SC12-12 için çevrimiçi göz atın veya pdf Ürün Kılavuzu indirin. Abt Powerline SC12-12 15 sayfaları. Valve-regulated sealed lead acid battery

When this charging method is used, the output
values will be as follows:
Initial Charge Current . . . . . 0.30C Amps (max.)
Charge Voltage:
1st Stage . . . . . . . . .2.45V/cell (2.40 to 2.50
v/cell, max.)
08
2nd Stage . . . . . . . . 2.275V/cell(2.25 to 2.30
v/cell, max.)Switching Current From
1st Stage to 2nd Stage . . . . . . . . . . 0.05C Amps
(0.04C to 0.08C Amps)
Note: This charging method cannot be used in
applications where the load and the battery are
connected in parallel.
C.V.C.C. CONSTANT VOLTAGE, CONSTANT
CURRENT CHARGE MODULE
The C.V.C.C. is a fully regulated automatic charging
module designed for batteries. There are two 6 volt
versions available; one for standby applications and
the other for cyclic applications. Also there are two 1
2 volt versions available, again one for standby
applications and the other for cyclic applications.
When interfaced with the appropriate AC or DC
power supply, the C.V.C.C. guarantees safe charging
and maximum battery life. Figure 18 is a block
diagram of the C.V.C.C.
Figure 18. Block diagram of C.V.C.C.
C.V.C.C.
CHARGE UNIT
The C.V.C.C. modules are protected from both the
short circuiting of their D.C. output voltage and from
being reverse polarity connected to the battery.
Detailed specifications are available on request.
Solar Powered Chargers
A battery is an indispensable component of any solar
powered system designed for demand energy use. Since
solar cells have inherent constant voltage
characteristics, Powerline SC can be charged directly
from the solar array using a simple diode regulated
circuit as shown in Figure 19.
Figure 19. BLOCK DIAGRAM OF A
SOLAR POWERED CHARGING SYSTEM
SOLAR CELL
OR PANEL
WHITE
{
Input
WHITE
LED
{
BLUE
Input Indicator
+
LED
GREEN
BLUE
LED
{
Charge Indicator
+
YELLOW
LED
{
BLACK
DC Output
+
RED
LOAD
BATTERY
In designing a solar powered system, consideration
should be given to the fact that in addition to normal
periods of darkness, weather conditions may be such
that solar energy is limited, or virtually unavailable
for long periods of time. In extreme cases, a system
may have to operate for 10 to 20 days with little or no
power available for charging. Therefore, when
selecting the correct battery for a solar application,
the capacity should be determined based upon
maximum load conditions for the maximum period of
time the system may be expected to be without
adequate solar input.
In many instances the battery capacity will be 10 to
50 times greater than the maximum output of the
solar panels. Under these circumstances, the
maximum output of the solar array should be
dedicated to charging the battery with no load
sharing or intervening control devices of any kind.
Naturally, in cases where the output of the solar array
exceeds the capacity of the battery, and weather
conditions are such that the potential for
overcharging the battery exists, appropriate
regulated charging circuitry between the solar panels
and the battery is recommended.
Remote sites and other outdoor applications is where
most solar powered systems are to be normally found.
When designing a solar powered system for this class
of application, a great deal of consideration must be
given to environmental conditions. For example,
enclosures which may be used to house batteries and
other equipment may be subject to extremely high
internal temperatures when exposed to direct
sunlight. Under such conditions, insulating the
enclosure and/or treating the surface of the enclosure
with a highly reflective, heat resistive material is
highly recommended.
In general, when designing a solar powered system,
consultation with the manufacturers of both the solar
panel and the battery is strongly advised.
Charging Voltage
The charging voltage should be chosen according to
the type of service in which the battery will be used.
Generally, the following voltages are used:
For float (standby) use. . . . . .. 2.25 to 2.30 volts
per cell
For cyclic use . . . . 2.40 to 2.50 volts per cell
In a constant voltage charging system, a large amount of
current will flow during the initial stage of charging but will
decrease as the charging progresses. When charging at
2.275 volts per cell, the current at the final stage of
charging will drop typically to a value of between 0.0005C
Amps and 0.004C Amps. When a battery has been charged
up to a level of 100% of the discharged ampere hours, the
electrical energy stored and available for discharge will be
90% or more, of the energy applied during charging.
Charging voltage should be regulated in relation to