| Tue
27 Nov
While we're still a ways away from doing any wiring
I do have a small job to do with the inverter.
In
Wothahellizat 1 the inverter was mounted under the
floor and we had a small trapdoor that allowed access
to the control panel. This worked OK but I always
wanted to add a remote panel so we could change settings
without groveling on the floor.
However
at over $500 for a remote panel it never happened.
Then
a few months ago we had to get the thing fixed so
while it was not being used I had a poke around. I
found that the control panel is a separate circuit
board (PCB) which is screwed to the inverter's enclosure
and connected to the main PCB with a simple 20-way
ribbon cable.
Hmmm,
this looks promising. I should be able to make my
own cable that's long enough to allow me to remotely
mount the display.
The control panel, the inverter's case
has been removed.
Here we see the control panel (yellow
line) and the original connecting ribbon cable (blue
line).
As
the cable only interfaces to an liquid crystal display,
a few LEDs and some pushbuttons there are almost certainly
no high-frequency signals that will be upset by a
longer cable, so I head down to the local electronics
store to buy some 20-way cable and two connectors.
No
luck, they have 40-way cable but no connectors. I
buy a metre of cable ($0.81) and return home figuring
to pirate the connectors from the cable I'm replacing.
When
I return though I realise that there are two other
cables that are used for functions we don't require,
ie the official remote display connection and a connection
for combining multiple inverters.
I
remove the IDC (Insulation Displacement Connectors)
connectors (yes I know that's tautologous, like PIN
number) from these cables, split my newly purchased
40-way cable in half, and press the connectors onto
it.
Pressing a connector onto the cable.
I'm sure there are special tools for this, but even
in my days working in electronics we simply used a
vice.
Having
made my new cable I plug it in and power up the inverter.
Everything seems to work, so for the time being I'll
consider this a good idea.
So
there you have it, if you have one of the large Trace
inverters you can buy the official remote display
for $500+, or make your own for 81 cents.
NOTE:
Obviously this will void any warrantee, and be
very careful about the pin 1 orientation of the
cable as getting that wrong could prove to be
very expensive.
Sat
1 Dec
I'm installing the heavy wiring from the batteries.
This means running some pretty fat wires through the
lounge room to the shunts in the electronics area.
Shunts?
What are shunts?
Shunts
are very accurate resistors used to measure large
currents.
For
small currents you normally just connect the wires
directly to the meter.
For small currents the meter can be
connected in series with the wire carrying the current.
But
with larger currents, usually over 20 amps or so,
it's common to let the bulk of the current bypass
the meter and just allow a small (and proportional)
amount to be tapped off to activate the meter's mechanism.
This
is partly because the meter would be too large if
it were built to handle large currents, and also because
the meter is often mounted remotely from the wire
through which the main current is flowing. Usually
such wires should be kept as short as possible and
it doesn't make sense to detour to a meter several
feet or even yards away.
Therefore
we employ a shunt. A shunt is just an accurate resistor,
when a current passes through it a proportional voltage
is developed across it. This is why they are specified
as for example a 100A 50mV shunt, which means that
if 100 amps are flowing through the shunt you will
measure 50 millivolts across it.
Therefore
a meter with a 50-millivolt movement that is connected
across the shunt will fully deflect the needle when
there is 100A flowing, half deflect at 50A etc.
A schematic of a shunt with a remote
meter connected.
 
And a couple of shots of the real thing.
You can also see the inverter in the background and
two 175A circuit breakers (one for each battery bank)
on the left of the top photo.
The
actual resistor part can take many forms and may show
file marks, cuts, solder dabs etc. This is not rough
manufacturing, it's how the shunt is tuned to exactly
the right resistance.
Sun
2 Dec
Peter is cleaning his excavator today. It hasn't been
cleaned in four years and the pile of muck left behind
in the wash bay is enormous.
Not all the muck is on the ground,
Peter looks a little grubby after cleaning the excavator.
Mon
3 Dec
Back onto wiring the batteries today. We want to get
a rudimentary system running without doing too much
temporary wiring that has to be removed.
The left hand battery bank. The wires
emerging from the floor are from the bank on the right
hand side of the lounge room.
The heavy wires running from the battery
banks up to the circuit breaker and shunt area.
The shunt area doesn't look so neat
now. Despite not wanting to do much temporary wiring
most of this will have to go.
A wider view showing the solar regulator.
Tue
4 Dec
We finally have enough infrastructure in place to
charge batteries with the two solar panels from the
Landcruiser.
The
Landcruiser's two Kyocera 120W panels can now be used
to charge our batteries in the truck.
Wed
5 Dec
I've finished most of the plumbing up to and including
the pump and external connections. I've never seen
so many hose clamps in my life, I already had dozens
from Wothahellizat 1 plus I purchased several a few
days ago and today I took delivery of another 80!
Due to an oversight I have to run the
tank outlets through the thick steel body bracing.
It's not hard to see where all the
clamps have gone I guess, there's eight in this tiny
area.
The accumulator, pump and control valves.
A pseudo schematic of the plumbing
in the tank and control valve area. "In"
comes from the outside world and "Out" goes
to the pump, accumulator, various taps, HWS etc.
Thu
6 Dec
Peter is still servicing his excavator. I'm still
working on the plumbing.
Fri
7 Dec
Well done all those who spotted an apparent fault
with my high-current wiring from the batteries. Although
it wasn't all that obvious the implication of some
of the previous text was that I had batteries, several
feet of wire, then the circuit breakers. Something
like this.
Now
this is not a very clever setup, you should protect
wires as close as possible to the current source,
(in this case the batteries) not eight feet away.
What happens if a short circuit develops somewhere
within that eight feet?
I
do in fact have some Mega fuses bolted directly to
the positive battery terminal of each bank, the only
reason I didn't show them before is that I stuffed
up the photo.
A 175A Mega fuse bolted directly to
the battery terminal.
The
circuit breakers are really just used as isolation
switches. As you can see the fuses are 175A which
is the same as the breakers, it would make better
sense to use fuses rated a little higher so that in
the event of a problem further downstream of the breakers
they would trip before the fuses blew which of course
would be cheaper and easier to rectify. But I'm using
what I've got.
While
on the subject of using fuses to protect wires let's
look at a common scenario, that of running a thick
wire DC bus around the vehicle and tapping off the
main circuit with small wires for lights, 12v appliances
etc.
When the wire shorts out it tries to
conduct too much current, it will overheat and possibly
catch on fire.
Most
appliances are fused but this may only protect the
appliance, what about the wire? It's typical for such
wires to be run all around the place on their way
to the appliance. If it should for example pass through
a steel bulkhead at point "A", vibration
can cause the insulation to become worn (because you
didn't use a grommet :-) and the wire to short circuit
to the steel.
It
almost certainly won't be up to the job of conducting
the available current and the result will be a meltdown
and/or fire.
Therefore
it makes sense to add a fuse at the point the small
wire branches from the large one. This fuse should
be rated well below the capacity of the wire.
Now when the wire shorts the fuse blows
instead of the wire.
Sun
9 Dec
Still mucking around with plumbing, it's not that
the system is overly complicated, but there just seems
to be a lot of detail to attend to. For example we
have a water meter to measure our usage, but for some
reason no plumbing fittings like meters and valves
have built in mounting points. Maybe they are designed
to be used with old-fashioned steel pipes that would
hold things in place, but in these days of nylon connections
and hoses you need to provide some extra mechanical
support.
Like
the meter below, I want the face to appear through
a panel, but with no mounting points on the device
I have to bodge up something myself.
The rear of the meter showing some
timber spacers that allow the dial to protrude just
the right amount through the panel, and a steel strap
to hold it in place.
Tue
11 Dec
I've got some good news and some bad hews. The good
news is that you can buy generators really cheaply
these days. The bad news is that that's just what
we will probably have to do, buy a new generator.
Here
in the workshop we often use a 6.5KVA diesel generator
to top up the batteries on overcast days like today.
It's a noisy thing and we stick it outside so we only
hear an annoying hum.
But
when that hum turns to a pop and fades to nothing
I run to investigate.
The
machine has stopped and there's a whiff of smoke in
the air. That's OK, it has been smoking a little lately.
But the smoke doesn't stop, in fact it gets worse.
The
bloody thing is on fire.
I
disconnect it and push it further from the shed, then
run inside and grab the first fire extinguisher I
can think of, a tiny powder unit.
This
has little affect so I grab another, the new extinguisher
is larger but the problem is access, because this
is an enclosed "silent" generator there
is no ready access to the internals, and it's the
internals that are on fire.
I
poke the nozzle in through air vents and an access
hatch but it has little affect. Then I start removing
the side panels while Chris tries to direct some powder
at any flames that appear.
It
soon becomes apparent though that the fire is dying
out of its own accord, thank goodness this is a diesel
generator, with a near full tank of petrol I may not
have been so keen to get close.
Two dead fire extinguishers and a dead
generator.
Some of the internal wiring.
All
this makes me think about access, despite having an
endless supply of fire extinguishers they were of
little use because we couldn't get access to the source
of the flames.
Because
this is a "silent" generator it's fully
enclosed, and although you can access everything it
takes tools and time, neither of which are in abundant
supply when a fire is on the loose.
Now
I always make things with access and maintenance in
mind, most panels are removable, brackets bolted rather
than welded etc. But I think about spending a few
minutes with a spanner while maintaining, not a few
seconds while fighting a fire.
So
from now on I think I'll pay more attention to this
aspect of the design.
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