Showing posts with label door. Show all posts
Showing posts with label door. Show all posts
Wednesday, October 1, 2014
Make a Door Bell with Memory Circuit
On occasion it may be useful to know when a visitor has called in your absence. This is especially true in the case of an enforced absence when a visitor is expected. Confusion reigns supreme on these occasions.
The circuit here helps to rectify the ’ situation by providing a memory for the doorbell. On your return a LED will advise you whether or not a visitor called. The circuit is powered by the bell transformer via diode D1 and capacitor C1. This provides a d.c. voltage level sufficient for the memory’. Under normal conditions (with no one ringing the doorbell) transistor T1 will be switched off and T2 will be conduc- ting to provide a form of latch for T1. Obviously LED D3 will never light under these conditions! Now our visitor arrives! With a joyful cry of Avon calling’ they press the doorbell — only to lapse into total embarrasment when there is no answer! However our circuit now leaps into action. Via D2 and R 1, the doorbell switch S1 provides a base drive current to T1 which . switches off. T2 and, in passing, i LED D3 on. `&low thm transistor i ’latch’ (T2) swings the other way and T1 is held on by the current path to the positive supply through S2 (normally closed) R5 and R6. The unfortunate visitor goes away totally deflated but the LED will indicate his past presence’l On your return the LED will be noted and the circuit reset’.
This is carried out by simply pressing S2 which breaks the base currents path holding T1 on causing this transistor to switch off. In doing so the LED will be switched off and T2 will be switched on. The ’latch’ will be back in the original position where T1 is held off by the fact that R5 is effectively in parallel with R2. A further refinement would be to provide an automatic reset when the front door is opened. ln this case S2 is a switch operated by the opening door. However the LED must then be mounted outside the door (poss- ibly in the doorbell switch housing) or the LED will be off by the time you get into the house to look! On the other hand a second circuit could be built as a ’memory’ for the automatic’ memory and then it would be no problem to open the door! This second circuit will of course require a reset switch!
The circuit here helps to rectify the ’ situation by providing a memory for the doorbell. On your return a LED will advise you whether or not a visitor called. The circuit is powered by the bell transformer via diode D1 and capacitor C1. This provides a d.c. voltage level sufficient for the memory’. Under normal conditions (with no one ringing the doorbell) transistor T1 will be switched off and T2 will be conduc- ting to provide a form of latch for T1. Obviously LED D3 will never light under these conditions! Now our visitor arrives! With a joyful cry of Avon calling’ they press the doorbell — only to lapse into total embarrasment when there is no answer! However our circuit now leaps into action. Via D2 and R 1, the doorbell switch S1 provides a base drive current to T1 which . switches off. T2 and, in passing, i LED D3 on. `&low thm transistor i ’latch’ (T2) swings the other way and T1 is held on by the current path to the positive supply through S2 (normally closed) R5 and R6. The unfortunate visitor goes away totally deflated but the LED will indicate his past presence’l On your return the LED will be noted and the circuit reset’.
This is carried out by simply pressing S2 which breaks the base currents path holding T1 on causing this transistor to switch off. In doing so the LED will be switched off and T2 will be switched on. The ’latch’ will be back in the original position where T1 is held off by the fact that R5 is effectively in parallel with R2. A further refinement would be to provide an automatic reset when the front door is opened. ln this case S2 is a switch operated by the opening door. However the LED must then be mounted outside the door (poss- ibly in the doorbell switch housing) or the LED will be off by the time you get into the house to look! On the other hand a second circuit could be built as a ’memory’ for the automatic’ memory and then it would be no problem to open the door! This second circuit will of course require a reset switch!
Monday, September 8, 2014
Electronic Security Door Key Wiring diagram Schematic
A different Electronic Security Door Key Circuit Diagram of electronic lock very simple, one and does not need a lot of materials in order to it is manufactured. The right keys of code should be stepped with the right line, so that is activated the optocupler IC2. If from error is stepped switch that does not belong in the combination, then the lock is trapped. In order to we restore the regular operation of lock, it should we press switches S1 or S12.
Electronic Security Door Key Circuit Diagram
Switch S1 makes Reset of lock externally and the S12 internally, the door. The Code the schema as he is connected it is 147 and it can change, very easily, changing the connections in the switches of keyboard. The optocupler IC2, can drive any exterior schema as Relay etc, ensuring simultaneously electric isolation the two diagram. The schema can be also supplied from a battery 9V.
Part List
R1-7-9=1Kohm
R2-3-4-5=100Kohm
R6 =10Kohm
R9 =47Kohm
IC1 = 4066
IC2 =4N25
Q1-2=BC550
S1...11=Push button sw or keyboard
S12=Push button normal closed
All resistors is 1/4W 5%
Subscribe to:
Posts (Atom)