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Saturday 23 March 2013

Breadd Board.....

How to Use Breadd Board.....


BREAD BOARD....

A breadboard (protoboard) is a construction base for prototyping of electronics. The term is commonly used to refer to solder fewer breadboards (plug board).

Because the solderless breadboard does not require soldering, it is reusable. This makes it easy to use for creating temporary prototypes and experimenting with circuit design. Older breadboard types did not have this property. A stripboard (veroboard) and similar prototyping printed circuit boards, which are used to build permanent soldered prototypes or one-offs, cannot easily be reused. A variety of electronic systems may be prototyped by using breadboards, from small analog and digital circuits to complete central processing units (CPUs).


Connections on Breadboard
Breadboards have many tiny sockets (called 'holes') arranged on a 0.1" grid. The leads of most components can be pushed straight into the holes. ICs are inserted across the central gap with their notch or dot to the left.
Wire links can be made with single-core plastic-coated wire of 0.6mm diameter (the standard size). Stranded wire is not suitable because it will crumple when pushed into a hole and it may damage the board if strands break off.
The diagram shows how the breadboard holes are connected:
The top and bottom rows are linked horizontally all the way across as shown by the red and black lines on the diagram. The power supply is connected to these rows, + at the top and 0V (zero volts) at the bottom.
I suggest using the upper row of the bottom pair for 0V, then you can use the lower row for the negative supply with circuits requiring a dual supply (e.g. +9V, 0V, -9V).
The other holes are linked vertically in blocks of 5 with no link across the centre as shown by the blue lines on the diagram. Notice how there is separate blocks of connections to each pin of ICs.
Large Breadboards
On larger breadboards there may be a break halfway along the top and bottom power supply rows. It is a good idea to link across the gap before you start to build a circuit, otherwise you may forget and part of your circuit will have no power! 


Building a Circuit on Breadboard


Converting a circuit diagram to a breadboard layout is not straightforward because the arrangement of components on breadboard will look quite different from the circuit diagram.
When putting parts on breadboard you must concentrate on their connections, not their positions on the circuit diagram. The IC (chip) is a good starting point so place it in the centre of the breadboard and work round it pin by pin, putting in all the connections and components for each pin in turn.


The best way to explain this is by example, so the process of building this 555 timer circuit on breadboard is listed step-by-step below.
The circuit is a monostable which means it will turn on the LED for about 5 seconds when the 'trigger' button is pressed. The time period is determined by R1 and C1 and you may wish to try changing their values. R1 should be in the range 1kDescription: ohm to 1MDescription: ohm.
Time Period, T = 1.1 × R1 × C1
IC pin numbers     


IC pins are numbered anti-clockwise around the IC starting near the notch or dot. The diagram shows the numbering for 8-pin and 14-pin ICs, but the principle is the same for all sizes.

Components without suitable leads

Some components such as switches and variable resistors do not have suitable leads of their own so you must solder some on yourself. Use single-core plastic-coated wire of 0.6mm diameter (the standard size). Stranded wire is not suitable because it will crumple when pushed into a hole and it may damage the board if strands break off.

Building the example circuit
Begin by carefully insert the 555 IC in the centre of the breadboard with its notch or dot to the left.
Monostable Circuit on Breadboard






Then deal with each pin of the 555:

1.     Connect a wire (black) to 0V.
2.     Connect the 10k resistor to +9V.
Connect a push switch to 0V (you will need to solder leads onto the switch)
3.     Connect the 470 resistor to an used block of 5 holes, then...
Connect an LED (any colour) from that block to 0V (short lead to 0V).
4.     Connect a wire (red) to +9V.
5.     Connect the 0.01µF capacitor to 0V.
You will probably find that its leads are too short to connect directly, so put in a wire link to an unused block of holes and connect to that.
6.     Connect the 100µF capacitor to 0V (+ lead to pin 6).
Connect a wire (blue) to pin 7.
7.     Connect 47k resistor to +9V.
Check: there should be a wire already connected to pin 6.
8.     Connect a wire (red) to +9V.
Finally...
  • Check all the connections carefully.
  • Check that parts are the correct way round (LED and 100µF capacitor).
  • Check that no leads are touching (unless they connect to the same block).
  • Connect the breadboard to a 9V supply and press the push switch to test the circuit.
If your circuit does not work disconnect (or switch off) the power supply and very carefully re-check every connection against the circuit diagram. 





Sunday 17 March 2013

An electric motor is an electric machine that converts electrical energy into mechanical energy.
In normal motoring mode, most electric motors operate through the interaction between an electric motor's magnetic field and winding currents to generate force within the motor. In certain applications, such as in the transportation industry with traction motors, electric motors can operate in both motoring and generating or braking modes to also produce electrical energy from mechanical energy.
Found in applications as diverse as industrial fans, blowers and pumps, machine tools, household appliances, power tools, and disk drives, electric motors can be powered by direct current (DC) sources, such as from batteries, motor vehicles or rectifiers, or by alternating current (AC) sources, such as from the power grid, inverters or generators. Small motors may be found in electric watches. General-purpose motors with highly standardized dimensions and characteristics provide convenient mechanical power for industrial use.

Steps to Follow


The largest of electric motors are used for ship propulsion, pipeline compression and pumped-storage applications with ratings approaching a megawatt.
  • Electric motors may be classified by electric power source type, internal construction, application, type of motion output, and so on.
  • Devices such as magnetic solenoids and loudspeakers that convert electricity into motion but do not generate usable mechanical power are respectively referred to as actuators and transducers.
  •  Electric motors are used to produce rotary or linear torque or force.
Note:

Found in applications as diverse as industrial fans, blowers and pumps, machine tools, household appliances, power tools, and disk drives, electric motors can be powered by direct current (DC) sources, such as from batteries, motor vehicles or rectifiers, or by alternating current (AC) sources, such as from the power grid, inverters or generators. Small motors may be found in electric watches. General-purpose motors with highly standardized dimensions and characteristics provide convenient mechanical power for industrial use.
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Saturday 9 March 2013

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