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Electronic
house consists of six major units. They are
-
Remote operated
gate control
-
Automatic gate
light, call bell system
-
Auto adjustable
timer unit
-
Remote operated
electrical equipments
-
Touch sensitive
burglar alarm for internal security
-
Water level
indicator and controller in a tank
Some photographs of
this model
Remote operated gate control
This
unit is responsible for opening and closing the gates at the
pressing of a button on remote transmitter.
Automatic gate light, call
bell system
During day time, this unit generates a musical alarm, when
anyone entering the compound of the house. During night time,
at the entry of any person through the gate, the compound
lights are switched ON together with musical bell.
Auto adjustable timer unit
This unit can be used to operate an electrical equipment for a
fixed period of time. The circuit can be used for street
lightning, billboard illumination and water supply to the
garden where pump can be set to switch ON at one time and
switch OFF at another tome.
Remote operated electrical equipments
This unit replaces the conventional switchboards. Fans, lights
and other equipments can be operated and controlled using
remote controlled unit.
Touch sensitive burglar alarm for internal security
This simple circuit when connected to a metal locker or
cupboard generates an alarm when touched by an undesired
entity.
Water level indicator and controller
This indicates the water level in the water tank at four steps
F, H, L, E, i.e., Full, Half, Low, Empty. When the tank is
empty the unit automatically switches ON the water pump and
switches OFF when the water level reaches to full.
This multipurpose electronic house has been successful in
gaining public attention. It has won many prizes at state and
district level competition.
Prizes
:
·
First place in model display competition in CORONA-2004 a
state level inter collegiate and cultural fest held on January
14th and 15th of 2004 at Sri Bhuvanendra
College, Karkala.
·
First place in the intercollegiate model display competition
during ELECTROFEST-2004 held on 16th and 17th
January 2004 at Mangalore University.
·
First in model display competition in IMPRINTS-2003 held on 27th
and 28th of November 2003 at St Aloysius College,
Mangalore.
Conclusion
:
This
electronic circuit explained above is only a model, and
incorporated in a cardboard model house. These circuits can be
incorporated, and realized in a large scale.
Adjustable timer unit
There is a variety of outdoor light controllers available.
Some switch lights ON at the fall of dusk and OFF at the break
of dawn. Others switch lights ON at the end of dusk and OFF
after few hours. But for domestic use, where we require light
in the early morning also, these do not serve the purpose. The
circuit described here solves this problem.
It offers the
following features:
-
It switches ON
lights at about 6.00 PM and switches OFF at about 11.00 PM.
Again it switches ON lights at about 4.30 AM and switches
OFF about 6.00 AM. We can change this time by changing
simple components.
-
There are
separate ON and OFF switches for easy operation of the
system.
-
It use LED
indicators to detect deferent conditions of the circuit.
-
Preset control
to set the trigger time.
The circuit
comprises five sections.
1. Triggering
This
section is used to trigger the circuit at the fall of dusk. It
is configured around IC 1, which is working in the monostable
mode. A variable voltage is fed to trigger pin 2 of IC 1 via
LDR and VR 1. In the monostable mode of operation, the output
of IC 1 stays high as long as its trigger input stays bellow
1/3 Vcc.
At
night, the resistance of LDR is high, so the voltage at pin 2
is at a low level and hence the output of IC 1 goes high at
night. The output condition of IC 1 can be detected from LED
1. the output of IC 1 gives power supply to the next stage.
2.
Resetting
The
next section is used to reset two 4017 decade counter ICs used
in the counter section. This is also based on a 555 timer [IC
2]. Its trigger pin 2 is connected to capacitor C3 and
resistor R4. In the absence of supply, there is no voltage
across capacitor is bellow 1/3 Vcc and its output goes to a
high state. The voltage across capacitor C3 increases, so that
the voltage at pin 2 crosses 1/3 Vcc. The time period for
which the output stays in the high state depends upon resistor
R5 and capacitor C4 and is given by the relationship
1.1*R5*C4.
The
output of IC 2 is given to the reset pin 15 of decade counter
IC 3 and IC 4. These ICs are reset when IC 2 is triggered, and
as long as the output of IC 3 is in the high state, the
counters sty in the reset position.
3.
Oscillator
This
section is used to produce a square wave output. It is based
on IC 5 an NE 555. Its output frequency depends upon resistors
R6 and R7 and capacitor C5 and is calculated by the equation
1.443/(
(R7+2R6)C5)
The output
frequency is fed to the counter section.
4. Counting
The
counter section is used to count the output frequency from the
oscillating section. It uses two CMOS CD4017 ICs. The
frequency from oscillating section, IC 5, is fed to the input
pin of IC 3. IC 3 works as frequency divider and its output is
fed to the input pin of IC 4.
The
four outputs of IC 4 are combined by using diodes D1 through
D4. This combined output is given to the last section. If any
of the output is high, then the load is ON state. The
condition of this combined output is detected by LED 2.
5. Output
The
output section is used to switch the relay ON and OFF. It is
based on BEL 187 transistor. The relay is connected at the
collector of transistor. Diode D5 is connected to protect
transistor. The output from the counting section is fed to the
base of transistor through resistor R3. If the output from
counting section is high, it biases the transistor and thus
the relay is activated.
Working:
At
the fall of dusk, the resistance of LDR increases, so a large
voltage is dropped across it, resulting in a decrease in the
voltage at pin2.
When
the voltage at pin 2 drops below 1/3 Vcc, IC 1 is triggered
and stays in the high state still morning. Since the output of
IC 1 is high, the next three states get power supply.
When
C3 is fully charged, IC 2 is triggered and reset pins of IC 3
and IC 4 both get a positive value. Therefore, the first
outputs of both ICs are high. This condition changes when the
voltage across capacitor C4 crosses 2/3 Vcc, because then the
output of IC 2 goes to a low state and the reset pins of IC 3
and IC 4 get a negative pulse each. In this condition IC 3
gets ready to accept pulses from the oscillating section and
its outputs are changed.
For
each set of ten pulses from IC 5 the outputs of IC 4 are
changed one by one. The output time period of oscillating
section is about 540.5 seconds, i.e. about nine minutes. Since
IC 3 divides the output frequency from IC 5. IC 4 gets a time
period 9*10=90 minutes, i.e. one and half hours. So, the
outputs of IC 4 are changed every one and half hour’s
duration.
When
the controller is switched ON, the output Q0 at pin 3 of IC 4
is high and it turns on the load for first one and a half
hour. Then, the next output Q1 at pin 2 is high, which
switches ON the load for the second one and a half hour. Next,
output Q2 at pin 4 goes high, which switches ON the load for
the same period again.
When
the output Q3 at pin 7 is high it switches of the relay as pin
7 has no connection. Then, the output of IC 6 changes to Q4,
Q5, Q6 for each one and a half hour, and when it reaches
Q7(i.e. pin 6) the load is again switched on. After one and a
half hour, the output is changed to Q8 (pin 9). Since pin 9 of
IC 6 has no connection, it again switches OFF the relay.
At
the break of dawn, the resistance of LDR decreases, and the
trigger pin of IC 1 gets a positive voltage greater than ½ Vcc,
so that its output goes low which, in turn cuts off power
supply to the next three stages.
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