[0001] The present invention relates generally to an illuminated exit sign and, in particular,
to a control circuit for supplying AC and DC power to a plurality of series connected
light sources in an exit sign.
[0002] Many types of emergency exit signs are known in the art including those that operate
on either AC or DC power. Exit signs of this type frequently require two sets of illuminating
lamps, one set for AC operation and a second set for DC operation. Many of the known
emergency exit signs use incandescent light bulbs as an illuminating source which
use a comparatively high amount of power, thus draining a battery rapidly during DC
operation. Also, incandescent light bulbs have a tendency to burn out and must be
replaced periodically, adding maintenance costs to the overall cost of the exit sign.
[0003] It would be an improvement over the prior art exit signs to provide a single illuminating
source for both AC and DC operation which consumes relatively little power and which
has a comparatively long life so that it requires infrequent replacement.
[0004] It is an object of the present invention to provide a highly visible emergency exit
sign which requires infrequent maintenance.
[0005] It is another object of the present invention to provide a highly visible emergency
exit sign which requires infrequent maintenance.
[0006] It is another object of the present invention to provide an exit sign control circuit
that automatically charges a battery during AC operation and that, upon power failure,
switches to DC operation and increases the visibility of its display.
[0007] The above objects are inventively achieved in an emergency exit sign and control
circuit having light sources, which are preferably light emitting diodes, connected
in a plurality of series combinations each having a predetermined number of light
sources. The series combinations are connected in parallel across the output of the
control circuit. The control circuit applies continuous power to the light sources
during AC operation and charges a battery when required. An indicator on the exit
sign shows the charging state of the battery. When a power failure occurs, the control
circuit pulses battery power to the light sources causing the illuminated display
to flash. Battery power is continued until the battery reaches a predetermined minimum
voltage, at which time the control circuit shuts the light sources off, or until AC
power is restored, when the sign will again be continuously illuminated and the battery
recharged.
[0008] The present device thus provides an illuminated exit sign preferably using light
emitting diodes which provide improved visibility, use low power for longer DC operation,
and have a longer life for infrequent replacement. By connecting the light emitting
diodes in series combinations, a correct voltage drop may be supplied across each
light emitting diode without using series resistors. The elimination of series resistors
from the device reduces power consumption and improves visibility of the exit sign.
The present invention, thus, provides an improved exit sign having many features distinguishable
over the prior art.
On the Drawings
[0009]
Figure 1 is a perspective view of an emergency exit sign embodying the principles
of the present invention.
Figure 2 is a rear elevational view of a display portion of the exit sign of Figure
1, including connections for light emitting diodes in series combinations of three.
Figure 3 is an electrical diagram showing three series connected light emitting diodes.
Figure 4 is an electrical diagram showing two series connected light emitting diodes.
Figure 5 is an electrical diagram showing six series connected light emitting diodes.
Figure 6 is a circuit diagram of a control circuit for use in the emergency exit sign
of Figure 1.
[0010] In Figure 1, an illuminated emergency exit sign is shown generally at 10 having a
housing 12 and a display board 14 with the word "EXIT" marked thereon at 16 and arrows
pointing in opposed directions at 18. A second display board 14 substantially identical
to the first may be mounted in the other side of the housing 12.
[0011] Figure 2 shows a rear view of the display board 14 of Figure 1 having connections
20 for a plurality of light emitting diodes (LEDs). The connections 20 are arranged
to spell the word "EXIT" 16 and to form the arrows 18. For purpose of illustration,
an LED 22 is shown in dotted outline connected at connecting points 24 and 26. The
display board 14 includes first and second power connections 28 and 30 to which voltage
is applied to illuminate the LEDs 22 of the exit sign 10. By examination of Figure
2, it can be seen that the LED connections 20 are linked in series combinations of
three throughout the display board 14 and that each series combination is connected
in parallel across the power connections 28 and 30.
[0012] Figure 3 shows a series combinations 32 of three light emitting diodes 22 for use
in the display board 14 of Figure 2. A forward voltage drop of 2.1 volts is required
across each of the LEDs 22 for proper operation. Thus, the voltage drop required across
the combination 32 of Figure 3 is 6.3 volts. Since the display board 14 of Figure
2 includes only the series combinations 32 of three LEDs 22, 6.3 volts must be applied
across the power connection points 28 and 30 for proper operation.
[0013] Figure 4 shows two light emitting diodes 22 connected in a series combination 34
which may be used in place of the three light emitting diodes 22 of Figure 3. The
voltage required for application across the combination 34 of Figure 4 is 4.2 volts,
therefore, should the display board 14 of Figure 2 be arranged in such a way as to
include only LEDs 22 in series combinations 34 of two, a 4.2 volt power supply would
be required at power connecting points 28 and 30.
[0014] Similarly, Figure 5 shows six series connected light emitting diodes 22. For proper
operation, a 12.6 volt power supply must be applied across a combination 36 of Figure
5. Therefore, if the display board 14 of Figure 2 were arranged to include only light
emitting diodes 22 in series combinations 36 of six, a 12.6 volt power supply must
be applied to the leads 28 and 30. It may be seen from the foregoing that any number
of series connected LEDs may be used in the present device.
[0015] Figure 6 shows a control circuit 40 for applying power to the display board 14 of
Figure 2. The control circuit 40 includes a transformer 42, a bridge rectifier 44,
a comparator 46, a multi-vibrator 48, a voltage regulator 50, and transistors 52,
54, 56, 58, 60, 62, and 64, as well fas a variety of other circuit elements to insure
proper operation. A power line, such as a110 volt AC power line, is connected across
leads 66 and 68 of the transformer 42 producing, in a preferred embodiment, a 10 volt
AC signal at outputs 70 and 72 of the transformer 42. The 10 volt AC signal is applied
through test switch 74, the importance of which will be discussed hereinafter, to
inputs 76 and 78 of the bridge rectifier 44. A full wave rectified signal appears
at rectifier outputs 80 and 82 which is applied through resistor 84 to the voltage
regulator 50 at an input 88. The voltage regulator 50 of a preferred embodiment is
a 5 volt regulator and has a ground connection 90 and an output 92. The ground connection
90 is connected to circuit ground through three series connected diodes 94, 96 and
98. This results in the output voltage of the regulator 50 being raised by 6.3 volts,
or the sum of the 2.1 volt drop across each of the diodes 94, 96 and 98. The regulator
output is then fed through diode 100 to the power connections 28 and 30, which are
the same power connections as on the display board 14 shown in Figure 2.
[0016] The full wave rectified signal is fed through resistor 102 and filtered by capacitor
104 to produce an essentially DC signal. The DC signal is divided by voltage divider
resistors 106 and 108 and applied through resistor 110 to base 112 of the transistor
52. The application of power to the base 112 of transistor 52 causes the transistor
52 to begin conducting, which acts through resistor 114 to pull pin 116 of the comparator
46 below a threshold level. The resistors 118 and 120 had been maintaining the pin
116 above the threshold level, which in a preferred embodiment is 5.85 volts. Pulling
the voltage a pin 116 below the threshold level results in a low state being produced
at pin 122 of the comparator 46. The low is applied through resistor 124 to base 126
of the transistor 56 to cause the transistor 56 to assume a non-conducting state.
[0017] If AC power is interrupted, the transistor 52 will cease conducting and allow the
voltage at the pin 116 of the comparator 46 to rise above the threshold level which
will result in a high signal at the pin 122 of the comparator 46. The high signal
at the pin 122 is applied through the resistor 124 to the base 126 of the transistor
56, causing the transistor 56 to commence conducting and draw current through resistors
128 and 130. The flow of current through the voltage divider resistors 128 and 130
causes a voltage to be applied to base 132 of the transistor 58 so that transistor
58 is turned on which causes voltage from battery 134 to be applied to pins 136 and
138 of the multi-vibrator, or timer, 48. The application of power to the pins 136
and 138 causes output 140 of the timer 48 to oscillate. The oscillating signal is
applied to base 142 of the transistor 60 through resistor 144. Consequently, the transistor
60 switches on and off at the timer oscillation rate. The switching of transistor
60 operates through resistors 146 and 148 to cause the transistor 62 likewise to switch
on and off at the timer oscillation rate. Each time the transistor 62 is switched
on, it applies voltage from the battery 134 to the power leads 28 and 30 of the display
board 14, and each time the transistor is switched off, the battery voltage is disconnected
from the power leads 28 and 30. Therefore, interruption of AC line power to the circuit
results in the LEDs 22 in the exit sign 10 flashing at the oscillation rate of the
timer 48.
[0018] As the transistor 58 begins conducting, battery voltage is also applied through diode
150 to pin 152 of the comparator 46. Capacitor 154 is of sufficiently high capacitance
value to enable the pin 152 to remain high.
[0019] Should AC power remain off for a long period of time and the battery voltage drop
below the threshold set at the pin 116 of the comparator 46, the pin 122 will assume
a low state, cutting off the transistor 56 and in turn cutting off the transistor
58. This has the effect of disconnecting the battery 134 from the power connections
28 and 30.
[0020] Should AC line power resume, the transistor 52 again is turned on which results in
power being supplied to the load as described above. Pin 156 of the comparator 46
senses the battery voltage during AC power through resistors 158 and 160 and capacitor
162. Hysteresis is built into the comparator 46 by the provision of feedback to the
pin 156 so that upper and lower threshold levels are established for sensing battery
voltage. When the pin 156 reaches the lower threshold limit, indicating that the battery
134 voltage is low, a low state is produced on pin 164 of the comparator 46, and when
the pin 156 reaches the higher threshold limit, indicating that the battery 134 is
fully charged, a high signal is produced on the pin 164. A low state at the pin 164
turns on the transistor 64 which applies charging current to the battery 134 through
diode 166. A low state on the pin 164 also draws current through diode 168, which
is a light emitting diode, indicating that the battery is charging.
[0021] As the battery 134 charges it will eventually become fully charged causing the pin
156 to reach the upper threshold limit which produces a high state at pin 164. The
high state at the pin 164 turns off the transistor 64 and the light emitting diode
168 and applies a high signal to base 170 of the transistor 54, causing it to conduct.
When the transistor 54 is turned on, it draws current through light emitting diode
172 which indicates that the battery 134 is fully charged. The diodes 168 and 172
are preferably of different colors for ease of identification.
[0022] Operation of the normally closed test switch 74 to an open position disconnects the
bridge rectifier 44 from AC power enabling the control circuit 40 to switch to battery
power. The test switch, thus, tests the circuit operation and the condition of the
battery 134.
[0023] Thus, there has been shown and described an illuminated exit sign and a control circuit
that uses low power and long life light emitting diodes and that functions on AC or
DC power. Furthermore, during a power shortage, when an illuminated exit sign is needed
most, the light sources within the present sign flash drawing attention to itself.
The present invention also provides means for automatically charging a battery so
that the lights are illuminated at their brightest for the longest possible time during
a power outage.
[0024] As is apparent from the foregoing specification, the invention is susceptible of
being embodied with various alterations and modifications which may differ particularly
from those that have been described in the preceding specification and description.
It should be understood that I wish to embody within the scope of the patent warranted
hereon all such modifications as reasonably and properly come within the scope of
my contribution to the art.
1. An emergency sign having a housing in which are mounted a plurality of light emitting
sources connected to a control circuit for providing AC operation through a transformer
and a rectifier and for providing emergency operation from a battery characterized in that said plurality of light emitting sources (22) are connected in a plurality
of series circuits (32) each having an identical number of light emitting sources,
said series circuits (32) being connected in parallel, said control circuit (40) has
a voltage regulator (50) connected across said rectifier (44) with an output of said
voltage regulator connected to said parallel connected series circuits, a comparator
(46) in said control circuit having a first input (116) at a first threshold level
connected to said rectifier to trigger said first threshold level in response to signals
from said rectifier, a first output (122) of said comparator (46) transmitting a first
triggering signal upon the triggering of said first threshold level, a second input
(156) of said comparator (46) connected to said battery (134) and having at least
a second threshold level, a second output (164) of said comparator transmitting a
second triggering signal upon the triggering of said second threshold level, means
responsive to said first triggering signal to connect said battery (134) to said parallel
connected series circuits (32), and means responsive to said second triggering signal
to apply a charging current to said battery (134).
2. The emergency sign according to claim 1 characterized in that said means responsive
to said first trigger signal includes a multivibrator (48) that is connected to said
comparator first output (122) for alternately connecting and disconnecting said battery
(134) to said parallel connected series circuits (32).
3. The emergency sign according to claim 1 characterized in that said first input
(116) of said comparator (46) is connected to said battery (134), and means (56) are
connected to said first comparator output (122) for disconnecting said battery (134)
from said parallel connected series circuits (32) upon triggering of said first threshold
level.
4. The emergency sign according to claim 1 characterized in that a test switch (74)
is provided for disconnecting said rectifier (44) from said transformer (42).
5. The emergency sign according to claim 1 characterized in that said rectifier (44)
is a full wave bridge rectifier.
6. The emergency sign according to claim 1 characterized in that a plurality of diodes
(94, 96, 98) are connected in series between a ground lead (90) of said voltage regulator
(50) and a ground connection of said control circuit (40).
7. The emergency sign according to claim 1 characterized in that an indicator (168)
connected for indicating when said battery (134) is being charged.
8. The emergency sign according to claim 1 characterized in that said light emitting
elements (22) are light emitting diodes.
9. The emergency sign according to claim 1 characterized in that a filter (104) is
connected across the outputs of said rectifier (44) in parallel with a voltage divider
(106, 108) and a first active element (52) is connected between said voltage divider
and said first input (116) of said comparator (46).
10. The emergency sign according to claim 2 characterized in that a second active
(56) element is connected to said first output (122) of said comparator (46) and responsive
to said first trigger signal to transmit power from said battery (134) to said multivibrator
(48).
11. The emergency sign according to claim 2 characterized in that a third active element
(62) is connected to an output of said multivibrator (48) and to said battery (134)
and to said parallel connected series circuits (32) to apply power from said battery
(134) to said series circuits upon receipt of a signal from said multivibrator (48).
12. The emergency sign according to claim 1 characterized in that said means responsive
to said second triggering signal includes a fourth active element (64) that is connected
to said second output (164) of said comparator (46) and to said rectifier (44) and
said battery (134) to apply charging current to said battery (134) upon receipt of
said second triggering signal.
13. The emergency sign according to claim 1 characterized in that said second input
(156) of said comparator (46) has a third threshold level and said second output (164)
of said comparator (46) is responsive to triggering of said third threshold level,
a fifth active element (54) connected to said second comparator output (164) for response
to triggering of said third threshold level, and a second indicator (172) connected
to indicate the response of said fifth active element (54).