Electronics project notes/Common terms, useful basics, soldering
Boards and wiring
PCBs
Printed circuit boards (PCBs) refer to ready-made boards.
PCBs may be two-sided, or have three (or more) layers, where sandwiched layers usually purely have copper traces that allow more complex wiring than a double-sided board could give, with almost no added space.
Such PCBs are likelier to use SMT components, partly just because holes through everything are a design problem.
You can etch your own single-sided board fairly easily, and double-sided if you're adept. For more complex designs, or batches of a few dozen or more, it may become worth it to have them produced for you, though this is not particularly economical for hobbyists.
There are some PCBs that are useful to prototyping - such as pitch conversion boards.
Breadboard, protoboard, and such
Breadboard and Protoboard can refer to most boards mentioned below - solderless breadboards, raster/strip/perfboards, and more.
These are typically THT style and have 2.54mm (0.1") pitch, which means SIP, DIP and other packages, and wires up to roughly AWG 22, are also comfortable enough to use.
Solderless breadboards, a.k.a. plugboards, are plastic boards with rows/columns of friction locked holes, very usually at 2.54mm (0.1") pitch. The arrangement s usually to connect columns, with one or two rows above and below (most often used for Vcc+Gnd)
These have a little bit more capacitance than PCBs, stripboards, and such, so avoid these for high-frequency applications.
People regularly use some solid-core wires to plug around these things (even pre-cut, partly just because shops tend to sell them), and it can look like a rather neat variant of your drawn circuit.
Size is referred to by the amount of connection points.
Some common sizes include:
- 170 point is the cute tiny sort
- 270 point
- 400 point seems to be the average and common one
- 830 point is basically a long variant of 400 (16x5cm)
- 1280 point
- 1660 is basically two 830s under each other (16x10cm)
Stripboard (UK: Veroboard) refers to holed boards with all holes for a row (or short groups, e.g. tripad) connected using copper strips. You can cut through these strips as you need to. Whenever you can use the copper strips, this can save a bunch of wiring and mess, particularly on simpler circuits.
Maximum current varies, but never count on moving more than half an amp (the copper width is decent, but at holes it's at most half that, so current that has to go past those holes is problematic). You can cheat a little with solder, or perhaps using multiple lanes, but soldering in an appropriate-gauge wire is often a better and easier solution.
Perfboard / raster boards refers either to things with holes but no copper, (probably) more commonly, to boards with individual islands of copper, mostly for ease of soldering.
Exist in a bunch of varying looks and qualities.
Adjacent islands can be connected via channels of solder, longer-distance connections can be made with wires - a wiring pen can be handy if you have one.
Can be convenient when the circuit is somewhat complex, when stripboard would mean a lot of cutting and triboard isn't so convenient either.
Wiring pens/wiring pencils , wire-wrap, and the associated wire (UK: Verowire) are often used as an easy way to add individual between soldered points, particularly on perfboard.
Wire (usually copper with a thin plastic coating to insulate against other such wires) is often quite thin overall, and only for low currents (logic paths - fine for most 12-and-fewer-volts logic).
With a steady hand and some non-conducting adhesive tape (there are some specialists tapes) this can even be used for small-pitch / SMT components - which can be nice on protoboards.
See also:
- http://en.wikipedia.org/wiki/Breadboard
- http://en.wikipedia.org/wiki/Stripboard
- http://en.wikipedia.org/wiki/Perfboard
- http://en.wikipedia.org/wiki/Wiring_pencil
- http://elm-chan.org/docs/wire/wiring_e.html
- http://info.ee.surrey.ac.uk/Workshop/advice/grotwire/usingPen.html
- http://www.instructables.com/id/How-to-Prototype-Without-Using-Printed-Circuit-Boa/
Circuit drawing, circuit simulation
- Eagle [1]
- Fritzing [2]
- win, lin, osx
- LibrePCB [3]
- win, lin, osx
- Micro-Cap 12
- win
- KiCAD [4]
- win, lin, osx
- LTspice
..and many others (TODO)
See also:
Fixing in place
There's always hot glue., though it doesn't hold well on every surface.
If you want boards to be solidly in place, not contact anything near it,
but still be removable, the simplest solution may be to use one of:
- spacer nuts; use screws to actually fix
- PCB edge holder
- basically thin slots you slide the PCB into.
- e.g. a few plastic clips
- some project boxes have these along their length (for a single breadboard size)
Soldering
This is largely about soldering in electronics, though some of it applies well to soldering in plumbing as well.
For a wider context, see Soldering, brazing, and welding
Soldering irons - type and power
On temperature
Tip selection
On buying solder
On flux
"Solder paste"
Hints originating in physics and chemistry
Solder flows with heat
More on flux
More on tips
SMD and tips
Reflow soldering
Protecting things from heat
Protecting things from ESD
Unsorted hints
Further tools
Desoldering
Wick / braid
Wick, a.k.a. desoldering wick, a.k.a. desoldering braid, is useful to absorb most solder.
It's basically a thin strip/tube of stranded copper.
Used subtly enough, it can also clean up accidental solder bridges, and a few other tricks.
Press the wick to solder, using your soldering iron on top.
Once this heats things enough, there's a capillary-like effect that makes most of the solder flows into the wick.
You should not need much pressure at all - enough for basic contact, the heat should do the rest.
You will probably have an easier time with some flux under or in the braid.
You can get braid with flux, but adding flux just before use seems to work better -- though this may be a review of the cheap braid I have.
Using braid works a little better when your soldering tip is flat, delivering heat faster, also meaning that if you're holding the wich in place you're less likely to burn your fingers.
If you pull open the wick a bit you may get a little more absorbed
2mm-wide wick seems fairly general-purpose.
Wider can be nice for removing larger blobs.
Desoldering pump
Desoldering gun, desoldering station
On reflow soldering
Reflow for fixing
See also
- Video: How and WHY to Solder Correctly
- http://www.circuitrework.com/guides/7-0.shtml
- http://www.morsex.com/building/atoz.htm
- http://www.kpsec.freeuk.com/solder.htm
On technique
Good solder joints
Read https://learn.adafruit.com/adafruit-guide-excellent-soldering/common-problems
On (not) damaging components
Typical components
Battery packs
Your safety
Boxes, safety, weatherproofing
Some safety considerations
- Chassis grounding
- done for fire safety, human-shock safety,
- Pull resistant cable clamps
- Particularly on power cables, but useful for anything that avoids pulling on something weak via something stronger
- may also be water resistant
Splash-proof / waterproof box, and moisture resitance
- Enclosure
Tupperware is an easy and cheap splash-proof option - and often seals fairly well, to be decent against things like dew and rain with a minimal consideration, and perhaps a little hot glue to seal the holes you make for wires.
For serious projects you can buy nice-looking boxes and may may be IP-rated, and may react to heat better than, say, tupperware.
- Connectors
Usually most relevant is how condensation may affect closeby conductors.
Conformal coating, potting
Conformal coating refers to materials that don't conduct electricitly, that protect against forms of moisture (including condensation), fungus, corrosion (from salt or other), dust, heat and such.
Frequently acrylic, urethane, silicone, epoxy, or paraxylene, each of which have some specific upsides.
Usually applied as a thin layer (sprayed, brushed, or dipped). Sometimes potting[5] is used instead (note: potting has more direct thermal implications).
Keywords that might be handy while searching:
- electronic coating
- protective coating
- conformal coating
- (weather) protection/protective lacquer
- Various brands / product names - Kontakt chemie, Humiseal, etc.
Some common coatings:
- acrylic
- easy to apply
- good against moisture and such, not so good against abrasion, some chemicals, natural solvents
- silicone
- lower dielectric value than most others
- can stand more heat than some others
- arguably easier to repair than various others
- (poly)urethane
- resists many chemicals well
- not the healthiest to work with
- epoxy
- hard
- easy to apply (but warm)
- hard to remove
- resists many chemicals well
- not the healthiest to work with
- paraxylene
See also: