It's a bit ironic (in the Alanis Morrisette sense) because NetData was built by a small community on Reddit to be small, lightweight, easy to deploy, open source, etc. Now it looks like any other commercial enterprise monitoring product.
The wikipedia entry for emoji is missing this entirely, but "smileys" were quite popular in various instant messaging apps (AOLIM, ICQ) and web forums. I was fairly sure they go back as far the mid or late 90's but I can't seem to find any hard evidence of that.
(I was into computers at the time but didn't see the point of IM apps or forums when IRC and Usenet already existed.)
A really cool feature of Windows Live Messenger (perhaps also MSN Messenger before it?) was you that smileys were viral. You could add your own, and people could right-click on the ones you used to copy them to their own collection.
It was great! And in MSN Messenger you could assign any string to be replaced by the smiley (which were basically any image including animated gifs) so some people’s writing was totally unreadable as letter or phrases were replaced with these images. Fun times
Yahoo Messenger had amazing fun animated smileys, and it was a fantastic Instant Messenger as well. Too bad Yahoo went to dogs, I was hoping Yahoo Messenger got bought out by Microsoft so that beautiful UI could be integrated as MS Office chat. Instead, Micro$oft acquired Skype, mainly for its VOIP ability, and it took years to integrate it into MS Office as MS Teams, which is a boring tool (but it is effective for video conferencing and basic chat purposes).
I miss those animated smileys.
Even WhatsApp and other popular social messaging platforms (Instagram, Signal, etc.) don't have them. Instead, we got GIFs (whose online gallery takes ages to load in WhatsApp, in recent months, at least on my phone) and animated stickers. sigh
Not a UX designer, but having supported systems for decades I don't agree with your statement. If you got the system down to a single button that said 'Do' the user would still somehow screw it up.
They are pretty clearly targeting DIYers and enthusiasts who like tinkering with off-grid solar.
Grid-connected is an entirely different ball game. You will not see any open source projects there, or at least not any that anyone will want to use.
Let's think about why not. Anything grid-connected, you REALLY want a licensed electrician to plan and install. And competent electricians will NOT go anywhere near a piece of equipment that is not UL certified. A company producing equipment is NOT going to go through the expense of getting UL certified and then just release their design, PCB, and schematics for free.
And I want to be clear that I am a strong proponent of open source hardware, there are just certain situations where the incentives in reality just don't line up. This is one of them.
> Anything grid-connected, you REALLY want a licensed electrician to plan and install.
Have you heard of balcony solar?
It's a solar panel, a microinverter, and a standard wall plug. It doesn't need an electrician to install any more than anything else, you just plug it in. Outlets work both ways.
LibreSolar doesn't seem to be working on any inverters, but a complete open source system like this would be great.
If that wikipedia article is right, then balcony solar is not legal where I live (in the US). Here, we require a hard-wired, permanently installed automatic transfer switch that disconnects the solar generation from the grid when the mains power goes out. This is to protect line workers when working on downed lines.
It's probably coming soon for you, 30 states have bills announced or introduced legalizing plug-in solar and one (Utah) has already passed. They should be fairly uncontroversial.
Also, there's no need for a transfer switch in any grid-tied system, whether plug-in or hard-wired. Grid-tied inverters shut off automatically if there's no grid frequency to sync to.
"Transfer switch" refers to a specific kind of switch that transfers load between two sources. There is only one source (the panels) and one load (the grid) on a grid-tied inverter, so what you're saying does not make sense.
There are more complicated solar setups that do involve transfer switches, but they are not applicable to the balcony solar use case and remain uncommon even for hardwired rooftop solar.
In grid tied inverters with batteries the transfer switch can be built in to the inverter or it can be an external switch that the inverter talks to. Similar to how you would use one with a generator setup.
And indeed these are uncommon, mostly because they tend to be more serious devices. Victron and formerly Xantrex make nice ones, but the inverter alone probably costs more than a complete balcony solar installation.
For the solar balcony and more common rooftop solar setups there is only a simple disconnect, but both a transfer switch and a disconnect are the same thing: a (usually beefy) relay, but the transfer switch variety switches your house between the inverter and the grid whereas the disconnect just physically disconnects the inverters output. The downside of that setup is that if there is no grid but you do have solar that you still have no power.
Most of these wouldn't be able to power anything but the smallest installations anyway (300 W or so, typically), and don't have a battery to store any excess (as if there would be any...).
As soon as you add a battery it makes good sense to use the transfer switch: you can disconnect from the grid but the inverter can keep running to power your house and if you're lucky the solar will replenish it fast enough during the day that you can hold over for a while.
The big rooftop inverter that I have has a built in transfer switch but I'm not using it right now simply because I don't have a good way to route the wiring to and from the inverter. It is stuck in my garage with the main distribution panel on the other side of the house. In my old house in Canada that was all designed from scratch and there we had the house entirely off-grid with the transfer switch hooked to a genset if the power was out for longer than the battery could sustain us (48 KWh so that usually was good for a couple of days).
IIUC plug-in balcony solar is subtly different. It's basically aimed at grid-tie operation, connected by backfeeding through a standard 120V 15/20A branch circuit. On its own that's unsafe as you could have downstream loads drawing more than the 15/20A circuit ampacity, but I think the idea is still at the pinky-swear-it's-a-dedicated-receptacle-and-cross-your-fingers stage.
The units likely have "protected outlets" too that likely use an internal transfer relay to disconnect from the grid side, but at 15/20A it doesn't have to be terribly beefy.
Yes, they're an interesting little loophole device. They are likely not going to be legal in the long run because of the overload potential, even though in practice you'd have to work at that to make it happen. After all, these are typically no more than 300 to 500 W and angled in a very unfortunate way so likely not making full power. The wiring connecting them to the distribution panel is not going to sweat handling - again, potentially - that much more power over the 16A typical limit, that's just 2A more and you are more than likely not going to have that much consumption going on on that same circuit.
I have a similar situation here but at much higher power levels, a single underground cable from my garage to the house carrying 16A tri-phase and a whole raft of consumers in the garage itself. There too there is the potential for overload with both consumers and producers on the same cable. The solution there was to have a secondary distribution panel, breakers on both sides of the cables, for the consumers and for the inverter guaranteeing that none of the wiring in the panel or to the house or the consumers ever exceeds its rating.
This was by far the most cost effective solution, saved adding another ground cable and relieves the main distribution panel of a lot of current going in and out of the garage.
Just plug several units into a power strip ¯\_(ツ)_/¯.
Just curious - are you exporting power or zero export with a current monitor upstream of the main panel? Also same question regarding off-grid operation and a transfer switch ahead of the main panel.
I don't know what tri-phase breakers cost in NL but the second panel and feed-in breaker sound like the straightforward solution in the US too. Our wires cost considerably more, and we don't even have RCD in the breakers you'd use for that.
> Just plug several units into a power strip ¯\_(ツ)_/¯.
Hehe, ok. I think that's your insurance company calling on the other line.
> are you exporting power
Exporting 12 MWh / year or thereabouts.
> or zero export with a current monitor upstream of the main panel?
There is a current monitor (a Shelly tri-phase one), right now it is still economically viable to do so (though the utility companies are trying what they can to dissuade you by changing the deal through politics). If it is no longer then I will just install a battery and disconnect from the grid for the summer months.
And I'm not using a transfer switch because I don't have a battery to stabilize the system.
Well, technically those breakers are a manual transfer switch, only it is broken up into two halves and I can just disconnect the mains feed and run in island mode but I would still need to install a battery and a charger. House mains breaker off, solar on would be the house running entirely off the local stuff, I just don't trust that inverter without a battery behind it to be able to react quickly enough to load changes and by default it is set up to disconnect if the grid goes off, so you'd have to manually override that. The main issue with it being two halves is that you can not guarantee that the house net is in-sync with the grid at the moment you make the switch and that's a bad idea with a system this powerful, so I'd definitely get a proper automated one if I intended to do this for real, otherwise you might cause a load spike which could trip breakers and annoy the neighbors.
Right now I can't switch that on or off under load anyway because the large inverter would simply disconnect as well.
Tri phase breaker of the right amperage was about 150 bucks.
If I were to do this I would probably get a complete set from Victron, their stuff is amazingly well engineered, but if these open source people are going to make an inverter/charger combo then I might go for that and add a another manufacturers automated transfer switch.
An inverter is, complexity wise, not that much harder than a large switching power supply, there is some more instrumentation and some more rules but it isn't super difficult. It is much harder to make one that is commercially viable because those guys all cut corners to stay competitive. Ironically a proper case is probably the hardest part, there are also some larger inductors that might be tricky to source. And if you were to design one you should probably make the low voltage stuff (UI, CPU) on a completely separate board from the line voltage stuff and go for tri-phase right away because it is so much cleaner. Bonus points for modularity of the output stage.
Perhaps I'm in the wrong thread but there is no part of me that wants to DIY my own power electronics design. I've designed a few bucks and boosts professionally and chasing down those failure modes was a headache. Victron = solid hardware, openly-documented protocols, no cloud? Fahgettaboudit.
(then again maybe someday I'll hit some wall with off the shelf MPPTs and find myself wanting to go down that rabbit hole lolol. but honestly AC coupling seems cleaner in terms of things like fault protection on longer runs - fault on a stiff mains circuit -> breaker will trip. Fault on a circuit where the current/power is intrinsically limited to what the solar panels can supply -> ???)
I asked about the transfer switch / monitoring because I've looked at the same problem here, first with a generator now with solar. Incoming power service is on the complete opposite side of the house from where I really want the power handling gear. The manual two breaker thing is practical (for a generator at least), but not code compliant here (no positive lockout).
I would think Victron would have an option for a remote transfer (/disconnect) switch, but I haven't really looked into it yet. It would still have to get the grid phase timing somehow to line them up before connecting, so something more than merely a dumb contactor.
> Incoming power service is on the complete opposite side of the house from where I really want the power handling gear.
Same in my house.
> It would still have to get the grid phase timing somehow to line them up before connecting, so something more than merely a dumb contactor.
Then you'll want a synchronous one. They match phase before making the switch, which is one reason why it's nice if you use one tied to your inverter, which already has the capability to steer its phase to match the grid.
Are synchronous transfer switches a common thing, especially for residential / light commercial? The only references I could find are for data centers and the like with massive diesel generators. There's also the question of how an independent transfer switch would steer the phase, but nudging a Victron inverter like one phase-nudges a conventional generator would probably work.
But really an independent transfer switch wouldn't actually fully solve the problem - power at the main incoming service panel would still have to blip off-on for the downstream Victron to see the grid loss, disconnect from grid with the external transfer switch, disable anti-islanding, and then re-close the relay to backfeed up its own AC-IN. And even that would be a bit dodgy relative to proper certification for anti-islanding.
What one really needs for this topology is to move both the contactor and the current sense normally in the Victron, to the location of the incoming service panel. Which is why I was wondering aloud if they had a solution to do this, and coordinate with the inverter to maintain export rules, phase matching, etc.
I'm guessing the common answer is just run two sets of wires, as with generators.
A disconnect and a transfer switch are not a same thing, "transfer switch" refers to a specific type of switch in a specific role as I have described. Conflating the two is incorrect and benefits nobody.
> the transfer switch variety switches your house between the inverter and the grid whereas the disconnect just physically disconnects the inverters output
> That simply is a transfer switch that is built in.
Then in this comment:
> but both a transfer switch and a disconnect are the same thing
These statements are false, and the fact that the second one was written even after being corrected once makes me think they still do not understand.
This user appears to blast paragraphs upon paragraphs of irrelevant noise at anyone who responds to them so that either the comment has internal conflicts (as you noticed) or any criticism seems nitpicky.
We require transfer switches, but they do not have to be automatic transfer switches.
In the United States, you are one small piece of sheet metal[1] away from any number of interesting power set ups on your side of the utility.
This means a combination of two circuit breakers is now your transfer switch. This is legal with all utilities and NEC compliant, etc.
If you are willing to sacrifice perfectly uninterrupted power, you can dramatically simplify your grid tie - and open up many other possibilities on your side of the physical interlock.
Exactly. The main application of a transfer switch is that it is not going to cause your genset to backfeed into the grid. But for many solar installations that's exactly what you want anyway, so the disconnect logic for an islanding capable inverter is very much the same as for one that is exclusively grid connected, the big difference is that the islanding one will happily generate it's own phase clock if the grid is not present, but for that to work it has to keep its own system running and connected to the house distribution panel while the grid connection is down.
This is much easier to do if it is all integrated into the inverter itself, but that makes for an awkward bunch of wiring, because the inverters are typically not situated right next to the entry point for the grid connection. I'd have to rewire my distribution hookup completely for that kind of functionality, or to have a remote controlled disconnect while the inverter keeps feeding the distribution panel.
A transfer switch is much more applicable to emergency power or ship/shore power situations where you only use one power source at the time. For solar it is normally all on or all off or solar+battery(+wind) on all the time and backfeeding into the grid when it is available and grid power when solar+wind+battery are not available.
This can get complex in a hurry, fortunately there are a number of companies that make excellent components for these applications that you can just order and hook up and call it a day, without ever having to worry if your fancy setup has the right break-before-make order and whether or not it is code compliant. And they're not expensive compared to the rest of the gear you'll need.
99.9% of all inverters currently being sold has this functionality built in. That 0.1% remaining you will find in the second hand market and the bargain bin of Amazon.
Could the inverse process work? Design, then (crowdsource?) pay for UL certs?
Don't know the process for certification, but in the software side, I've heard from foss projects asking for money for, e.g, security audits
Bollocks. I've been making grid connected hardware for decades, there is nothing magical about any of that. You just need to be careful, use proper fusing and you need to know how to read the electrical code.
Competent electricians are licensed professionals who (1) stand to make money on selling gear and (2) have customers that hire them simply because they don't want the hassle or the liability. Obviously a licensed professional is not going to install your home brew inverter, but at the same time if you can design a homebrew inverter you probably don't need a licensed professional anyway.
I've rewired lots of homes and have never had an issue with any of this and designed my first inverter when I was 17 to power my room when my betters decided I should go to sleep and cut the power.
This stuff is not magic. If someone designs a modern open source inverter I'm definitely going to build and install it. Fortunately insurance companies here are reasonable: if your homebrew device wasn't the cause of the mishap then you are still insured.
The one thing they are very strict about is gas, because there is no such thing as a 'fuse for gas'. But if you've properly designed and fused your gear then it should be no less safe than any other grid connected device, even if the magic UL or TUV mark isn't there.
The big one is EMI, that can be hard to get right and you need some gear for this, which is why it pays off to pool the money for an open source design to be certified. And once certified of course the design is 'type approved' and frozen, so you can't change any of the hardware without going through recertification. This is expensive, but if you don't do it every other week should still be well within the means of a properly set up open source project.
Why the fearmongering? It's not as if we're 12 here.
If you can design and build your own inverter I would take it as read that you know how to read code and know how an actual inverter should function:
If you're grid connected and see valid phase on the input for a certain amount of time of matching phase and measuring voltage you can provisionally connect at exactly that phase and voltage but without injecting power. After that you are allowed to slowly ramp up your output by leading the phase (while raising the voltage within certain limits) as long as you observe the effect that you have on the grid. If the grid phase drops away or there is any other anomaly (such as a voltage drop or rise of more than x V/s you are required to immediately disconnect, there are many other disconnect requirements but that's the main one with respect to line worker safety.
Three disconnects within a short period of time = no reconnect attempts for a much longer time. If the situation persists that's a failure and you are no longer allowed to connect to the grid until there has been an intervention and an inverter reset.
If your inverter is of the islanding variety then the rules are slightly different, then the transfer switch only gets energized when you match voltage and frequency but in the meantime the (usually battery backed up) inverter can supply local consumers.
By the time you come up with the idea of rolling your own inverter you have either become familiar with the requirements (which differ from region to region, and which in a properly designed inverter are mostly a matter of tweaking firmware parameters) or you will have to do so because you realize your responsibilities.
Anybody up for this kind of project will with a high degree of likelihood have the required knowledge because that knowledge is a lot simpler to acquire than the knowledge to build an inverter that isn't going to result in you being laughed out of the room when your EE buddies come look at your creation.
I would expect you to do a better job than 95% of the imported ones that I've taken apart and which all had massive shortcuts taken, good enough to pass first inspection and a year into warranty, not good enough for long term safe deployment. This ranges from unsuitable connectors, low quality inductors, even lower quality relays, undersized FET boards, insufficient cooling, bad cast aluminum housings, in general bad housings (not rodent and/or insect proof) and so on.
Thanks, and I agree that a DIY-inverter designer should be able to meet grid-interconnection requirements (e.g. IEEE 1547-2018). With that said, I think case-by-base evaluation from the AHJ would be prudent without a UL listing... something that AHJs don't want to do.
I'd prefer to just put the DIY inverter behind a transfer switch (with an adequate battery bank and maybe a small propane generator)... with the grid as emergency fallback.
That's exactly the setup that I had in Canada with a windmill thrown in for good measure (which really helped in the winter, after we got the windmill up we never ran the generator again).
>Bollocks. I've been making grid connected hardware for decades, there is nothing magical about any of that. You just need to be careful, use proper fusing and you need to know how to read the electrical code.
I would say that rules out about 80-95% of DYI users.
DIYers and enthusiasts should still worry about their house burning down because one of these boards started a fire. An insurance company would investigate and find any excuse they can to deny payment.
Insurance covers the insured's own gross negligence. This is a trope up there with believing the "warranty void if removed" stickers.
The real reason this should give you pause is that you don't want your house to burn down regardless of an insurance payout. That is how your incentives remain aligned with the insurance company.
I’m not sure about your home insurer, but here in the UK, most home electrical wiring, including solar for example, is “notifiable” to building control and requires a qualified tradesperson to implement.
If you want to DIY everything you need self-build insurance.
I’m definitely not covered if I were to burn my house down with a dodgy inverter installation.
In many (most? all?) jurisdictions in the US there's a carveout to exempt DIY work from licensing requirements and to require insurance to cover it.
Many things you still have to get a permit and have it inspected afterwards just like a professional would. But if you skip that no one will ever notice unless it's major structural work (such as a new deck).
That said, if it's electrical and you skip the required inspection and then your house burns down and your work was at fault that might nullify your insurance but I'm not sure.
IANAL but I don't think that's true at all. Electrical work needs to comply with code standards (NEC). I'll eat my hat if an insurance company pays for a fire that was caused by using homebrew electrical systems.
I'd really like to see citations to the opposite. After all, the main function of most homeowners' insurance policies is to keep banks whole regardless what happens.
In my experience insurance companies just ask you a bunch of big-picture or specific questions (eg swimming pool), reserve the right to inspect even though they never do, and then jack the rates rather than trying to grok more unknowns.
I've never read an insurance policy where anything like this is explicitly mentioned. I suppose there is a legal path of being criminally charged by fire investigators for having performed unsafe wiring (non-Listed power handling equipment as part of the fixed wiring), and then the insurance company denying you because of that criminality. Or in states where DIY wiring is not illegal, perhaps declaring that the wiring itself is "illegal" (as it goes against the NEC (despite the NEC not being openly published as we generally expect from laws!)) and then hanging their hat on illegality regardless of criminality? But does any of this happen in practice?
Surely if insurance companies were concerned about fires caused by dodgy electronics, they'd address all of the people using non-NRTL-tested GENSYM brands from Amazon et al? They've got no ability to post-facto deny based on this (said devices aren't illegal), but they could surely make it an explicit condition of policies.
Like I said, I'm not a lawyer.. and I'm no longer a homeowner so I don't have an insurance policy. So I don't have a citation for you. I may be wrong about this, but I don't think that I am. If anyone who's in the know can help then I'd be okay with being proven wrong.
There are certainly cases where harmonic distortion is a problem for a device. It’s just that everyone is left guessing, and there’s an overblown fear of devices being harmed.
Sure. It’s just rarely what lay people associate with “sensitive”. Most customers are worried about small electronics with switching mode power supplies that wouldn’t have a problem with just about any power source.
I wouldn’t run some AC motors, old AC clock, ham radio, or many other things on some generators.
The line is open to interoperation and never defined by the manufacturer. It’s blanket liability avoidance that confuses customers.
Should is doing a lot of work there. The reality is most don’t. These are people who don’t understand minimum conductor size trying to DIY a solar system.
This project isn't being marketd to people who call up a company to white-glove the whole-home installation end-to-end. This is for DIYers who have enough knowledge to tinker with self-designed solar projects but not the EE degree required to engineer some of the more specialized equipment themselves.
I'll give a good example: I use solar to power a ham radio station for a weekend in the summer. However, nearly ALL of the equipment you can buy for the production and storage of solar power emits some degree of radio-frequency interference, which is bad when your whole goal is to power a very sensitive radio.
When it comes to charge controllers in particular, there are exactly two companies that claim to make RFI-quiet MPPT controllers. One has mixed reviews (some people say they work great, some say they are not any better than anything else), and one is very good but also very expensive for what you get. So, more open design and community feedback from people like me might get the cost of a reliable RFI-free charge controller down to where it should be.
That's especially nasty when you're doing LF or VLF because the frequencies of the switches in those things are right in the middle of the bands that you are trying to receive.
Great article, but I recommend reading it in your browser's Reader Mode if available. The scrolling-magazine-article format made it quite difficult for me to navigate.
As a ham radio operator and a radio enthusiast in general, I love shortwave radio and wish it would make a comeback. However, I would be even happier if we as humans figured out how to co-exist peacefully enough with one another to make it fully and finally obsolete.
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