User Guide

ManualsBrandsSnap Circuits ManualsElectronicsSnap Circuits Jr. SC-100 Electronics Exploration Kit | Over 100 STEM Projects | 4-Color Project Manual | 30 Snap Modules | Unlimited Fun

(Part designs are subject to change without notice).

Note: If you have the more advanced Models SC-300, SC-500, or SC-750,

there is additional information in your other project manual(s).

The base grid functions like the printed circuit boards found in most

electronic products. It is a platform for mounting parts and wires (though the

wires are usually “printed” on the board.

The blue

snap wires are just wires used to connect other components, they

are used to transport electricity and do not affect circuit performance. They

come in different lengths to allow orderly arrangement of connections on the

base grid.

The red and black

jumper wires make flexible connections for times when

using the snap wires would be difficult. They also are used to make

connections off the base grid (like the projects using water).

The

batteries (B1) produce an electrical voltage using a chemical reaction.

This “voltage” can be thought of as electrical pressure, pushing electrical

“current” through a circuit. This voltage is much lower and much safer than

that used in your house wiring. Using more batteries increases the “pressure”

and so more electricity flows.

The

slide switch (S1) connects (ON) or disconnects (OFF) the wires in a

circuit. When ON it has no effect on circuit performance.

The

press switch (S2) connects (pressed) or disconnects (not pressed) the

wires in a circuit, just like the slide switch does.

Resistors, such as the

100Ω resistor (R1), “resist” the flow of electricity and

are used to control or limit the electricity in a circuit. Increasing circuit

resistance reduces the flow of electricity.

The photoresistor (RP) is a light-sensitive resistor, its value changes from

nearly infinite in total darkness to about 1000Ω when a bright light shines on it.

A light bulb, such as in the 2.5V lamp (L1), contains a special wire that glows

bright when a large electric current passes through it. Voltages above the

bulb’s rating can burn out the wire.

The

motor (M1) converts elecricity into mechanical motion. Electricity is

closely related to magnetism, and an electric current flowing in a wire has a

magnetic field similar to that of a very, very tiny magnet. Inside the motor is

three coils of wire with many loops. If a large electric current flows through

the loops, the magnetic effects become concentrated enough to move the

coils. The motor has a magnet inside so, as the electricity moves the coils to

align them with the permanent magnet, the shaft spins.

The

speaker (SP) converts electricity into sound. It does this by using the

energy of a changing electrical signal to create mechanical vibrations (using

a coil and magnet similar to that in the motor), these vibrations create

variations in air pressure which travel across the room. You “hear” sound

when your ears feel these air pressure variations.

The

whistle chip (WC) contains two thin plates. When an electrical signal is

applied across them they will stretch slightly in an effort to separate (like two

magnets opposing each other), when the signal is removed they come back

together. If the electrical signal applied across them is changing quickly, then

the plates will vibrate. These vibrations create variations in air pressure that

your ears feel just like sound from a speaker.

The

LED (D1) is a light emitting diode, and may be thought of as a special

one-way light bulb. In the “forward” direction (indicated by the “arrow” in the

symbol) electricity flows if the voltage exceeds a turn-on threshold (about

1.5V); brightness then increases. A high current will burn out the LED, so the

current must be limited by other components in the circuit. LEDs block

electricity in the “reverse” direction.

Some types of electronic components can be super-miniaturized, allowing

many thousands of parts to fit into an area smaller that your fingernail. These

“integrated circuits” (ICs) are used in everything from simple electronic toys to

the most advanced computers. The music, alarm, and space war ICs (U1,

U2, and U3) in Snap Circuits

are actually modules containing specialized

sound-generation ICs and other supporting components (resistors,

capacitors, and transistors) that are always needed with them. This was done

to simplify the connections you need to make to use them. The descriptions

for these modules are given here for those interested, see the projects for

connection examples:

(+)

HLD

OUT

(–)

TRG

IN1

(–)

IN2

IN3

OUT

IN1

(+)

OUT

IN2

(–)

Music IC:

(+) - power from batteries

(–) - power return to batteries

OUT - output connection

HLD - hold control input

TRG - trigger control input

Music for ~20 sec on power-up, then hold HLD to (+) power

or touch TRG to (+) power to resume music.

Alarm IC:

IN1, IN2, IN3 - control inputs

(–) - power return to batteries

OUT - output connection

Connect control inputs to (+) power to make five alarm

sounds, see project 22 for configurations.

Space War IC:

(+) - power from batteries

(–) - power return to batteries

OUT - output connection

IN1, IN2 - control inputs

Connect each control input to (–) power to sequence through

8 sounds.

-4-

About Your Snap Circuits

Parts

Our Student Guides give much more information about your parts along with a complete lesson

in basic electronics. See www.snapcircuits.net/learn.htm or page 45 for more information.