Christmas lights are just the only example that came to mind in the U.S.A.

I would personally prefer to have a 13A fuse on an extension cord
plugged into a 15A outlet so that the fuse would blow close to where I'm
using the cord instead of having to traipse through a building to the
breaker panel.
I would think that you'd want to open the (both) hot(s). Much like how
you want a double poll breaker to open both hots on a 240 V domestic
load in the U.S.A.

Blowing / opening one hot would still leave live power via the other hot
in a dual hot cord.

XMAS lights are fused because they can be daisy-chained; the next strand
plugged into the end of the previous strand. As such, the strand closest
to the mains outlet sees the total load of all strands. Expecting consumers
to observe the limit of 3 strands is wishful thinking. So, a 5A fuse in
every plug ensures that whichever strand is "first" will open.

Similarly, expecting consumers to consider each of the individual loads they
plug into a 99c 18AWG extension cord is wishful thinking.
US plugs (for consumer use) tend to be really poorly made. The blade material
may be flexible, the mount in the (molded!) plug may be flimsy so the blades
don't remain parallel, folks might cut off the earth conductor (to fit to a
two-prong outlet/extension cord) or use an adapter that does the same thing
(and fail to earth the required connection, XMAS lights can be found plugged
(two prong) into an adapter that is screwed into a light socket (! no earth),
etc.

OTOH, plugs for industrial use are very robust (because the manufacturers
don't want to have to replace them!). Ditto plugs used in hospital settings.
I salvage power cords from discarded (clothes) irons. They tend to be made of
something that more closely approximates "rubber" (vs. thermoplastics), have
better conductors (to handle the higher load) and are longer (than, for
example, the cord on a toaster)
A socket, here, is just a preformed piece of metal that tries to pinch
the blades of the plug. They are "stamped out" for pennies.

Worse, there are receptacles that can be wired by inserting a conductor
into a hole in the rear of the device (instead of putting it under and
around a screw) for a sort of "friction fit". As homeowners are
allowed to make such repairs/replacements, this is an often used
alternative (the screw connection is also present, just ignored!)

To make matters worse, loads will often be "daisy chained" through
such devices -- instead of a hard connection to pigtails feeding each
device in a box.
*On* the wall (as in "fastened")? Such equipment, here, would be freestanding;
set on the floor, on top of a TV, etc. but always "portable". The service
connection would be bound to a particular point but the customer side of
the connection would float.
They are notoriously abysmal, here. Ditto with POTS installers. If you
request new service, you'll find a length of cable run ON THE SOIL to your
home's service connection. If you want three drops, they will route the
cable up and over the roof, and down the appropriate exterior walls to
enter through a hole that they will bore through your outer wall.

[No basements/attics as they aren't needed -- no snow load so flat roof
is relatively common and architecturally expected; no frost heave (frost
line is ~4 inches) so shallow footings (18") and service trenches (our
sewer line is just a few feet below ground)]

If you want a drop on an *interior* wall, then things get tricky!
The center void in the interior wall needs to be located on the
roof. A hole drilled through and a plastic conduit installed
(just to perforate the roof). The cable is fed through the conduit
and the perforation around the conduit sealed with a petroleum
product. Inside the house, the perforated wall void is located
and a hole drilled into the drywall to fetch the cable end.

The cable feed (on the soil) will stay there for months before someone
will come around to bury it (just a few inches under the soil for
cosmetic reasons. The thinking seems to be to get you *service* as
quickly as possible -- so they can start billing you for it -- and
worry about the niceties of the installation, later. (the cable
company uses an ORANGE cable that is very obvious as it lays on the
ground)

Yes, the stovetop on ours can dissipate 9KW (1200+1200+3600+3000+100W)
with another 4KW (max(3000,4200,1300)) in the oven proper. I assume
there are some smarts in the appliance to "schedule" the drive to individual
heating elements.

(I know some of the induction cooktops only plan on two elements being
active concurrently -- no doubt to save on drive electronics. But, I
don't know if they are smart enough to time-division multiplex the drive
so that all of the stovetop burners can be used at reduced duty cycle)
Virtually all "circuit protection devices" are remotely located, here,
in the load center -- near where the main service enters the home.
(some kitchens may have a sub-panel to economize on wiring). But,
in general, appliances would have their own "power switches" as
part of their design -- assuming the notion of "OFF" makes sense.

To support "old work", one can purchase GFCI receptacles that can
provide that functionality at the outlet (instead of in the load
center). If located as the "first" (closest, electrically, to the
load center) outlet, the balance of the outlets on that branch
circuit can be protected as "loads" to that first unit.

I've been reviewing "electric kettles" to make boiling water
independant from the stove -- to reduce the wear and tear on the
(hard to replace) heating element in the stovetop AND to minimize
the chance of boilover (which necessitates a cleaning of the stovetop)
I also think this may reduce the amount of heat thrown into the
kitchen in the process.
One can purchase separate stovetops and ovens, here. But, the stovetop
tends to be the lion's share of the power consumption (see above).

You can buy a small "single burner" heating element (like to heat a
pot of water) but it would tend to be slower in doing so (e.g., I
boil water -- half a gallon at a time -- on the stove's 3600W element
set to HIGH).

Kitchens tend to attract "gadgets". But, experience will teach you not
to indulge those whims if you are concerned with where to site or store
them! E.g., my cavatelli maker hides in the garage for 350+ days out
of the year (cuz making cavatelli from scratch is too tedious to do
that often!). Ditto pizelle maker, pasta maker, cannoli tubes,
artichoke stands, cheese/meat grinder, bread pans, casserole dishes,
etc. WHEN you need them, they are invaluable. But, the rest of the
time, they are just "things" begging for a place to hide!

This can get tedious with some of the larger bits of kit (e.g., the stand
mixer is large and bulky and TOO OFTEN finds its way back into the
kitchen: "I'm getting too old for this shit!"

[Our kitchen (food prep area) is relatively small -- ~150 sq ft. So,
the storage space there is precious. And, is relatively easy to fill
when you consider flatware, kitchen utensils, pots/pans, foodstuffs,
etc. that you rely on EVERY day. Counterspace doubly so as you don't
want to sacrifice parts of it to storing larger devices if not going
to be used regularly. (We discarded our countertop toaster/convection
oven in favor of a stove with dual ovens just to reclaim that bit of
counterspace! When I bake cookies, I rely on the top of SWMBOs 42x54"
"map cabinet" for an extra 16 sq ft of cooling racks!)]
Refrigerators often have a dedicated branch circuit so the circuit
isn't accidentally tripped, putting those foodstuffs at risk.
None of our appliances require tools to "disconnect"; each
has some form of plug/socket arrangement -- though access to
it may be difficult (e.g., pull out the stove, refrigerator,
dishwasher to gain access)

Microwave ovens are just countertop appliances (in most cases; some
are wired in place but most are as replaceable as a toaster).
We moved our microwave onto a different branch circuit to increase
the margin available on the countertop circuits.
Some homes will have "instant hot water" (a small, tankless electric water
heater that can bring small quantities of water to "boiling" nearly instantly.
This dispensed via an additional spigot on the sink). Others may have
a "real" hot water heater under each sink -- this to reduce the time to
having hot water at that location. E.g., it's probably a 40ft run UNDERGROUND
from our water heater to any of the loads it services.
This depends on the company's positioning. Some products (dishwashers,
washing machines) are advertised as "quiet". It is a means of
distinguishing between different product offerings within a manufacturer's
line. We, for example, have to rely on "alarms" for these devices
to tell us when they are "done". And, the alarms are hardly large enough
to be heard throughout the house -- being "one-time" events, if you don't
hear it when it alarms, you miss it completely: "Has my wash finished?"

Many other products intentionally -- and obviously -- attempt to deceive.
Witness "puffy" pickup trucks that are just lots of air behind their
sheetmetal skins. Garbage disposals tend to have a similarly sized motor
encased in a (hollow) plastic outer skin to make them APPEAR heftier. etc.

So, they fit *into* the wall? Is the wiring concealed in the wall and
routed to the outlet(s) from within?

There is a product here called "Wiremold" that can be entirely surface
mounted (junction boxes as well as cable runs). But, it would typically
not be found in most homes (kitchens). A "Plugmold" product provides
similarly (permanently) mounted "outlet strips"

Basements/garages/exteriors will often have surface mounted junction boxes
with cable runs in EMT or rigid conduit, usually required by local code
(to protect the wiring). E.g., I run all of my exterior network cabling
in EMT with water-tight fittings as it makes for a cleaner looking installation
and affords some protections against physical damage.
As I said, a duplex receptacle would be about 1"x3" and sell for as
little as 77c or as much as ~$10 (QTY 1 -- though most would be purchased
in much larger quantities) depending on the features desired (ampacity,
cosmetics, tamper resistance, etc.)

You can (just barely -- and with many qualifications) install one into
a Jbox of ~10 cu in internal volume. A single gang device typically
exposes a 2x4" opening, covered by a 3.5x5" decorative plate

Yes, you can buy duplex outlets that have USB-A and/or -C chargers built
in (I think 3.6A total). But, as our outlets are relatively small, this
makes for a crowded outlet if USB devices try to share that space with
a pair of mains powered devices:

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I'm not sure if this is a good, long-term solution (if you already have
an abundance of outlets, already) as a failure in that charger now requires
the outlet to be replaced (instead of just unplugging and discarding a small
plug-in charger)

And, as most outlets (in rooms other than the kitchen) are located just
above the floor level, the value of them in those places is dubious
(do you have a surface nearby on which you could set the device(s)
being charged?)

I wonder how gas can be rated in KWh. That must asssume some sort of
gas-to-electricity converter machine.

The easy way would be to compare direct gas heating with resistive
electric heating, both of which are crazy inefficient.

There is a movement here to eliminate gas to Save The Earth. Berkeley
CA forbids running gas to new-construction homes. I'm sure that will
keep Climate Change from affecting Berkeley.

Outside the UK you'll probably get redirected to:
https://www.bbc.com/news/business-58090533

On Mon, 10 Jun 2024 10:35:11 +0100, Martin Brown
Wood and coal are nasty, with lots worse by-products than CO2. We
theoretically outlaw burning wood in San Francisco when weather
conditions are wrong, but that's not enforced.

It's cold here so we leave the gas heat on all the time. When it's
cold and foggy we can hit as much as $300 a month for gas+electricity,
which are on the same bill. People with air conditioning can pay much
more, but a/c makes life possible in many parts of the USA.

Our regular tariff has DELIVERED electricity running about 15c/KWHr. The
electrons cost about 4c but add another 10c to get them to your home!

There are additional taxes, surcharges, "meter" charge (for the "privilege"
of being able to receive electricity), etc. Last month's 640KWHr cost us
$130. This will likely climb to ~1500KWHr this month and for the next
few months (air conditioning is a HUGE electrical load -- it drops to 80F
around midnight and is up above that shortly after sunrise)

But, we also are not particularly good at conserving energy; I bake a
couple of times each week, all of our meals are hot, a gallon of hot water
for tea each day, a 16cu ft freezer (in the garage! :< ) and 20 cu ft
refrigerator, at least one TV on most of the day, etc.

[I abhor *cooking* with gas so gas is just DHW and GFA.]

Plus, all of the "vampire" loads -- the cordless phones, cell phones,
ereaders and tablets, TVs and HiFis, microwave oven, stove, refrigerator,
dishwasher, washer, dryer, a dozen UPSs, 15 monitors, at least three
computers in use (plus others "sleeping"), modem, router, amplified
speakers, DVR, media tank, garage door opener, clocks, printers, scanners,
etc. Nothing has a "hard" power switch, anymore (even the damn fans have
"remotes"!).
Our "meter charge" is $15/mo. There are 7 different "taxes".
Here, the load needs to be addressed more than the supply. E.g., the ACbrrr
is ~14KW and runs at ~30% duty cycle. As floor plans here tend to be "open",
there is no practical way to reduce the cooling load. With minisplits and
intelligent controls, we could conceivably arrange to shift the active load
to different rooms to keep our peak load below whatever an array could
deliver (most seem to be 6KW to 10KW arrays and, obviously, don't help with
your late day/overnight cooling loads!)

But, minisplits are so "industrial" looking. When someone comes up with
a way to retrofit the evaporators to the individual *vents* (running the
plumbing through the existing ducts), then they will see more residential use
(beyond just in garages).

Any surplus that you deliver to the grid would be compensated at 5c/KWHr
(the value of the electrons!) and purchased BACK from them at ~20c (taxes
and fees) when the sun has set.

I.e., every day you would consume all of your stored charge plus more!

(Our two "all electric" neighbors see $300+ monthly bills every month -- and
complain about how cold their houses are (heat pumps) in the MILD winter)