Cost effective backup system, with future solar
PeteS
Registered Users Posts: 9 ✭✭
I have reliable and relatively affordable grid energy. I'm currently using about 8kWh/day, but that includes an electric range and electric hot water heater. The house is new to me, I didn't choose what's in it, I plan on getting a gas range and could change to an on demand gas (propane) hot water heater, although there's nothing wrong with the electric hot water heater. This isn't so much about saving money as it is having immediate backup power for my sump pump, refrigerator, etc., and having longer term backup power if the grid gets knocked out for an extended period of time. Without the electric range and electric hot water heater, I would be good using 3-4kWh/day, keeping the electric hot water heater would add 2kWh/day, although hot water seems relatively non-essential.
I want to start with the backup system, then add solar later. I'm good with purchasing something like eight Surrette 6V S-550 428Ah batteries, or something similar. That provides me with 2-3 days of power at 50% discharge (roughly 10kWh of usable power).
If I'm using the system primarily as a big UPS, is one manufacturer/product better at managing battery charge levels than another? Assuming I do my part maintaining a set of flooded lead acid batteries, whose product will be more likely to maximize the life of my batteries, which will likely be in a float state most of the time? Even if the grid doesn't go down, does it make sense for me to purposely cut grid power on a regular basis (e.g once every 2-4 weeks) so the batteries do discharge a certain amount, then recharge?
At the moment, I'm between getting:
1) an Outback VFXR3648A, plus I believe I would at a minimum need the Outback Mate3 controller
2) an SMA Sunny Island 6048-US plus the SMA Smartformer
I realize those are two completely different types of systems, with different plusses and minuses. Those two Outback products combined are half the cost of the two SMA products. A fairer comparison (power-wise) seems like it would be a pair of VFXR3648A inverters plus the supporting products, compared to the SMA SI and Smartformer. From what I've read though, at that price point, the SMA SI and Smartformer seem like the better solution than two VFXR3648A inverters with the Mate 3 and Hub10. If I understand it all correctly, the SMA solution with the Smartformer does load balancing, and is more efficient than a pair of Outback VFXR3648A inverters. I also realize that when I do install my solar array, the SMA solution will be more expensive, purchasing an SMA grid-tie inverter vs. an Outback charge controller. But the AC coupled SMA design just seems more logical to me.
Am I okay with only 120V, or do I need split-phase 240V? If I'm going with the cheaper Outback 120V system, then I don't have hot water, unless I install a tankless propane unit, which is an additional cost. If I go with the 120V Outback system, then some of the most efficient mini-split AC units on the market won't be compatible.
Feel free to pick apart my take and offer suggestions. Thanks.
I want to start with the backup system, then add solar later. I'm good with purchasing something like eight Surrette 6V S-550 428Ah batteries, or something similar. That provides me with 2-3 days of power at 50% discharge (roughly 10kWh of usable power).
If I'm using the system primarily as a big UPS, is one manufacturer/product better at managing battery charge levels than another? Assuming I do my part maintaining a set of flooded lead acid batteries, whose product will be more likely to maximize the life of my batteries, which will likely be in a float state most of the time? Even if the grid doesn't go down, does it make sense for me to purposely cut grid power on a regular basis (e.g once every 2-4 weeks) so the batteries do discharge a certain amount, then recharge?
At the moment, I'm between getting:
1) an Outback VFXR3648A, plus I believe I would at a minimum need the Outback Mate3 controller
2) an SMA Sunny Island 6048-US plus the SMA Smartformer
I realize those are two completely different types of systems, with different plusses and minuses. Those two Outback products combined are half the cost of the two SMA products. A fairer comparison (power-wise) seems like it would be a pair of VFXR3648A inverters plus the supporting products, compared to the SMA SI and Smartformer. From what I've read though, at that price point, the SMA SI and Smartformer seem like the better solution than two VFXR3648A inverters with the Mate 3 and Hub10. If I understand it all correctly, the SMA solution with the Smartformer does load balancing, and is more efficient than a pair of Outback VFXR3648A inverters. I also realize that when I do install my solar array, the SMA solution will be more expensive, purchasing an SMA grid-tie inverter vs. an Outback charge controller. But the AC coupled SMA design just seems more logical to me.
Am I okay with only 120V, or do I need split-phase 240V? If I'm going with the cheaper Outback 120V system, then I don't have hot water, unless I install a tankless propane unit, which is an additional cost. If I go with the 120V Outback system, then some of the most efficient mini-split AC units on the market won't be compatible.
Feel free to pick apart my take and offer suggestions. Thanks.
Comments
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I believe the Outbacks can be stacked in a 129/240v configuration, but as you noted, load balance can be an issue. I use a pair stacked in a master/slave 120v config and use an autotransformer for a 240v pump. I'm not well aquainted with the SMA product.
There are batteries designed for primarily float service (eg. telecom applications), but any lead acid battery will eventually die of old age. In telecom applications I think they tend to replace them every 7 or so years just because. A potential problem with L16 type batteries like the Surrette you mentioned is stratification of electrolyte in float. You don't necessaily need to discharge every 2 weeks, but should do a regular bulk/absorb cycle to mix things up.Off-grid.
Main daytime system ~4kw panels into 2xMNClassic150 370ah 48v bank 2xOutback 3548 inverter 120v + 240v autotransformer
Night system ~1kw panels into 1xMNClassic150 700ah 12v bank morningstar 300w inverter -
For purely backup power, Solar tends to be quite expensive--Even full time off grid (9+ months a year), it runs around $1-$2+ per kWH for most people. And if you are in a region with not too much sun during winter, you will usually need a good backup genset+stored fuel to get you through the winter.
For a "near normal" off grid electrical experience, around 3.3 kWH per day is a good start for planning. LED lights, Energy Star Fridge, well pump, washing machine, LED TV, Laptop computer--And lots of conservation.
If you can run on a genset during the day, and just need a little power at night (quiet time), then a 1 kWH per day system can be nice and very cost effective.
It would be good to convert your stove, hot water, and (possibly) drier to propane (or natural gas) if available. A lot less expensive and does not need a genset to keep things going (although, you can size a system to support such loads, if you wish).
My first suggestion, if your "outages" are on the order of a few weeks once a year, a genset (propane or diesel, possibly gasoline, especially if you have very cold winters) it usually cost effective.
If you are out for months (after an ice storm or hurricane, and assuming the storm did not take out your solar panels, and you do not use city water or sewage), off grid solar may be helpful.
I will do a quick design based on 3.3 kWH per day for a full time off grid home (basically a good size/conservative battery bank to run a fridge+lights+etc.). First the battery bank, 2 days of storage and 50% maximum discharge seems to be a pretty optimal setup (using our rules of thumb--for various reasons):- 3,300 WH per day * 1/0.85 AC inverter eff * 1/24 volt battery bank * 2 days storage * 1/0.50 maximum discharge = 647 AH @ 24 volt battery bank
- 647 AH * 24 volt battery bank * 1/0.77 panel+controller deratings * 0.05 rate of charge = 1,008 Watt array minimum
- 647 AH * 24 volt battery bank * 1/0.77 panel+controller deratings * 0.10 rate of charge = 2,107 Watt array nominal
- 647 AH * 24 volt battery bank * 1/0.77 panel+controller deratings * 0.13 rate of charge = 2,622 Watt array "typical cost effective" maximum
http://www.solarelectricityhandbook.com/solar-irradiance.htmlPortland
Measured in kWh/m2/day onto a solar panel set at a 31° angle from vertical (easier to clean shown off in winter):
Average Solar Insolation figures
(Optimal winter settings)
Assuming you are going to need some genset usage in winter, pick 2.96 Hours of Sun per day (December long term average) as the "break even" month:Jan Feb Mar Apr May Jun 3.42
4.13
4.46
4.25
4.14
4.15
Jul Aug Sep Oct Nov Dec 4.34
4.49
4.47
4.07
3.13
2.96
- 3,300 WH per day * 1/0.52 off grid AC system eff * 1/2.96 hours of sun per day = 2,142 Watt array "break even" December
There are other conservation measures that can help (besides lots of atic and wall insulation, double pane windows, efficient heating/air conditioning)--Heat Pumps (air source) for heating (cooling) and hot water are possible to run on grid solar.
Heat Recovery Ventilators can be very nice for "sealed homes"--However the fan(s) for HRVs can consume a fair amount of energy too.
Energy usage is a highly personal set of choices--My answers will not be yours. Your thoughts?
-Bill
Near San Francisco California: 3.5kWatt Grid Tied Solar power system+small backup genset -
One point not suggested is a hybrid system which has load shaving abilities, assuming peak billing periods, this configuration would allow the batteries to at least be active, rather than sitting in float for extended periods, inverter chargers which are stackable/expandable, solar could be added later and provide 120/240 V are available. The price of grid power is a determining factor, building a giant UPS for blackouts which may be very infrequent seems an expensive proposition, but that is of course just an opinion.1500W, 6× Schutten 250W Poly panels , Schneider MPPT 60 150 CC, Schneider SW 2524 inverter, 400Ah LFP 24V nominal battery with Battery Bodyguard BMS
Second system 1890W 3 × 300W No name brand poly, 3×330 Sunsolar Poly panels, Morningstar TS 60 PWM controller, no name 2000W inverter 400Ah LFP 24V nominal battery with Daly BMS, used for water pumping and day time air conditioning.
5Kw Yanmar clone single cylinder air cooled diesel generator for rare emergency charging and welding. -
Say you are around Portland Maine...
For a "near normal" off grid electrical experience, around 3.3 kWH per day is a good start for planning. LED lights, Energy Star Fridge, well pump, washing machine, LED TV, Laptop computer--And lots of conservation.
Your thoughts?
-Bill
3.3 kWH per day does seem like an easily attainable target for me without the electric stove and hot water heater. Thanks for posting all that info. I was roughly thinking a 2 kW solar array would probably be appropriate when I get to that step.
I have a 2800 W generator that I used at my previous house. Obviously using that is the cheapest option for backup, I would just need to install a transfer switch. But, if I'm planning on installing solar panels anyway, I want to be able to benefit from them when the electric grid goes down. I probably should be looking at a 120V system though.
I had an HRV in my last house and intend to put one in this house eventually. As you said, the fans in them do use a fair amount of energy, even a small unit can use close to a kWH per day, although it's really not essential in this house. My new house was built in 1958 and it needs lots of upgrades and improvements. The first improvement was to have a perimeter drain installed in the basement. In addition to the 1/3 hp and 1/2 hp sump pumps that were fairly standard, they were offering to install a third pump with battery backup for an additonal $800. I just felt that I would rather put that money toward a better battery bank and inverter that could power more essential items in the house than just a sump pump. That's what got me looking into a battery backup system first, with solar to come in the near future. -
You might consider an Outback Radian GS4048A. I use mine for backup power and offsetting grid power consumption, average about 9 kWh per day. For larger loads, like a water heater or kitchen range you'll need the GS8048A. The Radians are 120/240 volt.
Rick4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
Don't forget the Conext line by Schneider, 240Vac standard split phase, grid & generator interactive (2, AC inputs)
Powerfab top of pole PV mount | Listeroid 6/1 w/st5 gen head | XW6048 inverter/chgr | Iota 48V/15A charger | Morningstar 60A MPPT | 48V, 800A NiFe Battery (in series)| 15, Evergreen 205w "12V" PV array on pole | Midnight ePanel | Grundfos 10 SO5-9 with 3 wire Franklin Electric motor (1/2hp 240V 1ph ) on a timer for 3 hr noontime run - Runs off PV ||
|| Midnight Classic 200 | 10, Evergreen 200w in a 160VOC array ||
|| VEC1093 12V Charger | Maha C401 aa/aaa Charger | SureSine | Sunsaver MPPT 15A
solar: http://tinyurl.com/LMR-Solar
gen: http://tinyurl.com/LMR-Lister , -
PeteS said:Say you are around Portland Maine...
2.1 Kw Suntech 175 mono, Classic 200, Trace SW 4024 ( 15 years old but brand new out of sealed factory box Jan. 2015), Bogart Tri-metric, 460 Ah. 24 volt LiFePo4 battery bank. Plenty of Baja Sea of Cortez sunshine.
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For that size battery bank, I would be suggesting that ~2,400 to 3,000 Watt AC inverter would be a nice maximum size. If you need more peak wattage, you might think about a 48 volt battery bank and larger AC inverter. And you may need a larger battery bank (and solar array)... It is a vicious circle (more power, more battery storage, more solar array, more money). If you can keep the system small and use a genset (again smallish--don't oversize) to handle extraordinary loads--That would be a nice mix.
-Bill
Near San Francisco California: 3.5kWatt Grid Tied Solar power system+small backup genset -
If you do switch to propane down the road, convert to a propane generator. During a major outage the gas stations can't pump fuel and you will run out. Our town was evacuated for 7 days and 5,000 people left. Many tried to stay but they ran out of gasoline and it was hot and smokey without cooling. They came home to science projects in their refrigerators and had to take them to the dump. All of the grid tied homes had gasoline generators with 500 gallon propane tanks. Not a good plan!
A few of my grid clients had the SMA secure power inverters with LG inverter refrigerators and they ran during the day and did well unattended. You just have to plan for it!
Offgrid was a piece of cake as it is a normal day! Good Luck!"we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
Raj174 said:You might consider an Outback Radian GS4048A. I use mine for backup power and offsetting grid power consumption, average about 9 kWh per day. For larger loads, like a water heater or kitchen range you'll need the GS8048A. The Radians are 120/240 volt
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The battery bank that I had mentioned is 48V if run in series, which is what I would plan to do. Eight 6V 428 AH batteries. I have looked at the Conext inverters as well. Something like the XW+ 5.5kW seems to offer a lot for the price, although I've seen several negative comments about Conext inverters when used in a grid interactive mode. Have they worked out those bugs, or was that just from people not configuring them correctly? The Radian GS4048A is also a strong possibility. Thanks for all the feedback!
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It's possible to find negative feedback or comments on any product, all products have their strengths and weaknesses, how an individual reacts to an issue, emotionally or pragmatically, determines the language used. Having read some negative comments didn't dissuade me from the purchase of Schneider products, personally I'm satisfied overall with the products, support and performance, having said that, I'm not a fan boy by any stretch of the imagination, im just not her the fan boy type. Some products enjoy a fan base and seemingly can do nothing wrong, despite numerous problems, often it comes down to support from the manufacturer. My understanding is shortly after Schneider purchased Xantrex, the support was not great, however since then they've improved, or so it would seem.
Reviews are to be taken at face value, they seem to be highly polarized, either the best or worst, since people don't rant when satisfied, less is heard from them. Mistakes made by end users could account for a large percentage of issues, I don't know one way or the other, but I do understand people often don't take responsibility for thier mistakes, instead directing responsibility to the manufacturer. Just some thoughts.1500W, 6× Schutten 250W Poly panels , Schneider MPPT 60 150 CC, Schneider SW 2524 inverter, 400Ah LFP 24V nominal battery with Battery Bodyguard BMS
Second system 1890W 3 × 300W No name brand poly, 3×330 Sunsolar Poly panels, Morningstar TS 60 PWM controller, no name 2000W inverter 400Ah LFP 24V nominal battery with Daly BMS, used for water pumping and day time air conditioning.
5Kw Yanmar clone single cylinder air cooled diesel generator for rare emergency charging and welding. -
Well said! And if you search the early years of radian, there were some pretty unhappy users. A grid-tie battery based system is one of the hardest tasks for a Pro. You can imagine the amount of time for a novice to get up to speed.
It is not just write a check like many of the Boaters in Florida do. Take a trip (if you are brave) up/down the Inter-coastal water way in Florida. Be a good swimmer if you do"we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
I've put a bit more thought into this and gotten an estimate from NAWS. This is what I'm thinking about going with:Outback FLEXpower One with VFXR3524A inverter, FLEXmax 80 charge controller,...
4 - Surrette S-550 428 Ah FLA batteries, for 24V
8 - Canadian Solar 305 W panels, Vmp: 32.7V, Voc: 39.9V
panels would be run as four strings of two panels, two strings on the east side of my 5/12 pitched roof, two strings on the west
MidNite Solar MNPV4-MC4 combiner box, to run the four strings into a single FLEXmax 80
MidNite Solar DC surge protector, assorted cables, mounting hardware, etc.
I will install a manual transfer switch so I can use my Yamaha YG2800i generator if needed on cloudy days, during power outages. I won't be going off-grid, unless the grid goes down.
This system seems to do what I want it to do, which is to provide me with power during an extended grid outage without having to run a generator 24/7, and it will create more kWh than I currently use over the long term.
My main debate now is whether to add more solar panels. I don't have a south facing roof, the ridge of my roof runs almost due N-S. I've read several articles about putting panels facing both E and W, and there are some advantages to doing that, as long as you realize that electrical production will be significantly reduced compared to S facing panels. I could run four strings of three panels each. That's 3660W STC, but far less than that in my E-W orientation. Will the FLEXmax 80 handle that, but just be capped at 80A x charging voltage? I don't want to fry an expensive charge controller. Or should I just get a second charge controller if I want more panels, one for the E side of the roof, one for the W side? I think that FLEXmax 80 will take two string inputs (but not three), so the cost of a second charge controller is partially offset by not needing a combiner box.
Thoughts? Thanks for any input you are willing to provide. -
Hi Pete,
If you're going with east/west arrays you need to base the array size on getting sufficient power production to charge the battery bank in the winter. Winter production will likely be 1/3 that of summer. If you haven't already, go to PVWatts and enter the array data for your location. That will give you an estimate of what your array configuration will produce. The system will definitely be over paneled in the summer months, but you can set the current limit in the controller to 55 amps, which is a 13% charge rate for you battery bank. No harm will come to the charge controller by being over paneled. I would definitely use a combiner box and recommend getting a box that will take 6 strings, you may need it. Two controllers might work better, but I would't go to that expense without first trying virtual tracking with one controller.
Rick4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
Raj174 said:Hi Pete,
If you're going with east/west arrays you need to base the array size on getting sufficient power production to charge the battery bank in the winter. Winter production will likely be 1/3 that of summer. If you haven't already, go to PVWatts and enter the array data for your location. That will give you an estimate of what your array configuration will produce. The system will definitely be over paneled in the summer months, but you can set the current limit in the controller to 55 amps, which is a 13% charge rate for you battery bank. No harm will come to the charge controller by being over paneled. I would definitely use a combiner box and recommend getting a box that will take 6 strings, you may need it. Two controllers might work better, but I would't go to that expense without first trying virtual tracking with one controller.
Rick
Adding the AC Energy output of the two 1.8 kW arrays in December gives me 138 kWh for the month, which seems good to me since I think 3.5 kWh/day is a reasonable usage goal for me.
The output in May, June and July is 450+ kWh per month with DC to AC Size Ratio of 1.8. Using the ratio of 1.8 as compared to 1.0 only results in a loss of about 100 kWh of potential output (per year) due to the over-paneled array going into a single charge controller.
So I think my answer is to go with six panels on each face of the roof, instead of just four. I can do that as four strings of three panels each and still be well under the 150V max for the FLEXmax 80. For much more balanced output throughout the year, perhaps it would make more sense to put four panels on each roof face and another four panels vertically on the south facing side of my garage. That would bring my December output up to 186 kWh, but cut my May, June and July production down to about 400 kWh per month.
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I would try to avoid using 3 panel strings with a 24 volt battery bank. Down converting the higher voltage will cause increased heat production in the controller and will be less efficient. What about just adding another 2 panel string to each side. I like the idea of the south facing panels, although they would likely need their own controller.
Rick4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
Pete, did you adjust/calculate the output, based on the angle the PVs are set at, for each of the months? ie if aligned for winter, the actual summer output will be less than the optimal summer output.
KID #51B 4s 140W to 24V 900Ah C&D AGM
CL#29032 FW 2126/ 2073/ 2133 175A E-Panel WBjr, 3 x 4s 140W to 24V 900Ah C&D AGM
Cotek ST1500W 24V Inverter,OmniCharge 3024,
2 x Cisco WRT54GL i/c DD-WRT Rtr & Bridge,
Eu3/2/1000i Gens, 1680W & E-Panel/WBjr to come, CL #647 asleep
West Chilcotin, BC, Canada -
westbranch said:Pete, did you adjust/calculate the output, based on the angle the PVs are set at, for each of the months? ie if aligned for winter, the actual summer output will be less than the optimal summer output.Raj174 said:I would try to avoid using 3 panel strings with a 24 volt battery bank. Down converting the higher voltage will cause increased heat production in the controller and will be less efficient. What about just adding another 2 panel string to each side. I like the idea of the south facing panels, although they would likely need their own controller.Jan: 7.4 kWh/day
Feb through Sept: 10+ kWh/day
Oct: 9.0 kWh/day
Nov: 6.4 kWh/day
Dec: 6.0 kWh/day
That's better than I was hoping for. I just need to figure out if the wall mounted panels are feasible. My neighbor's house may partially shade them near the winter solstice. -
That sounds great, hopefully there is not too much shading. If so, better in the morning or evening. Keep an eye on the charging current, you don't want to cook those batteries.
Rick4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
If the system will ever grow 48V should be used and hi voltage charge controllers make this so very easy. Outback is suppose to have them out next year. A schneider CSW 4048 and its 600v mppt could be looked at. Are you sure you can't build a pergola in the yard to stay off your roof?"we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
Dave Angelini said:If the system will ever grow 48V should be used and hi voltage charge controllers make this so very easy. Outback is suppose to have them out next year. A schneider CSW 4048 and its 600v mppt could be looked at. Are you sure you can't build a pergola in the yard to stay off your roof?
Raj174 said:
Rick, what did you mean by this this? Cook them by undercharging, or overcharging?Keep an eye on the charging current, you don't want to cook those batteries.
Maybe I should consider a 48V battery bank. Since the batteries are primarily for grid outages, I was trying to keep costs down, but another $1400 for four more batteries and cables isn't a huge amount compared to the overall cost. The problem is that I may then consider a more expensive inverter, more panels, etc. -
PeteS said:Dave Angelini said:If the system will ever grow 48V should be used and hi voltage charge controllers make this so very easy. Outback is suppose to have them out next year. A schneider CSW 4048 and its 600v mppt could be looked at. Are you sure you can't build a pergola in the yard to stay off your roof?
Raj174 said:
Rick, what did you mean by this this? Cook them by undercharging, or overcharging?Keep an eye on the charging current, you don't want to cook those batteries.
Maybe I should consider a 48V battery bank. Since the batteries are primarily for grid outages, I was trying to keep costs down, but another $1400 for four more batteries and cables isn't a huge amount compared to the overall cost. The problem is that I may then consider a more expensive inverter, more panels, etc.
Pete,
Spring to Fall the arrays have the potential to produce more charging amps than is recommended for your 428 amp hour battery bank. Even with an east/west configuration, they may produce as much as 70 amps depending on your location. Max recommended for your bank is about 55 amps, so you might have to set the current limit in the controller. Just recommend keeping an eye on the charging once up and running.
Rick4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
I think I previously misunderstood something about the Schneider Conext SW inverters, as far as their abilities in grid-interactive mode. Especially since the Schneider gear is on sale right now from NAWS, I took another look at them, and I think that's what I'm going to go with. What I've primarily been interested in is having a system that can meet my basic electrical needs in an extended outage, secondary is reducing my current electric bill.
I lost power around Halloween for a day and a half, due to 60 MPH winds. I was actually lucky, most people in my town lost power for 3 or 4 days. I was running my old (~2000 hours) Yamaha inverter generator around the clock, but it's loud and stinky now. It would be great to just use it to supplement solar/battery backup when needed.
I'm now thinking about going with an SW 2524 Inverter, MidNite Solar E-panel, Conext XW MPPT 60 CC, Conext SCP, Conext Combox, a MidNite Solar array combiner, four Surrette S-550 6V 428 Ah batteries, six 305 W Canadian Solar panels, plus assorted surge protection, cables and panel mounting hardware. I could go with eight 305 W panels, but I don't think that makes economic sense. It may be current limited by the CC during the good solar months, and I'll still need to rely on the generator during bad winter weather.
So, I think I'm happy with all of that. I'm wondering about the Conext battery monitor. I don't think I need it, it's surprisingly expensive, and Schneider doesn't even show it in many of their system diagrams. I'm guessing that between a multimeter and a hydrometer, I can do a better job understanding the state of my batteries than the battery monitor can?
I need to find out what edition of the NEC my state/town follows and figure out what my town's building/electrical inspector expects. I was reading an article the other day that described how some NEC sections related to solar power were not clearly defined, or required the use of equipment that may not have even existed, but much of that was fixed in the 2017 NEC. Many places still are on the 2011 NEC though, for better or worse. I guess my biggest concern related to that is related to the combiner box, shutdown switches and AFCI breakers in the DC side of things.
Also, thanks for all of your input. You have all been very helpful. -
Good choice and yes skip the battery monitor. It really is not needed in this application. Often the locals do not care about back-up but you should follow all the requirements to keep your fire insurance legal. Have a disconnect for the solar outside and if you mount solar on the roof do exactly what is required. The internal GFI to the cc is fine for a ground mount. I would use all of the Schneider AC & DC boxes as they are designed for your inverter and less problems with both the locals for docs and schneider themselves if warranty issues arise."we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
In thinking about number of panels, a couple of things to keep in mind.
1. In most climates, the panels will rarely put out rated (STC) power. Normal operating cell temperature (NOCT) rating, ~75% of STC is likely closer to real life output in most places. Cold, high altitude locations may get close to or even better than STC, but most of us see more like NOCT. In this case, 8x305x.75=1830w. At 25ish volt bulk charging ~73a. The controller won't draw that much, but not as overpanelled as it might appear at first using STC numbers.
2. Where having more panels is helpful is on lightly overcast days, and in low winter sun. The panels still produce, but at a reduced rate. This can be important off-grid, but maybe less so in your application.Off-grid.
Main daytime system ~4kw panels into 2xMNClassic150 370ah 48v bank 2xOutback 3548 inverter 120v + 240v autotransformer
Night system ~1kw panels into 1xMNClassic150 700ah 12v bank morningstar 300w inverter -
PeteS said:I think I previously misunderstood something about the Schneider Conext SW inverters, as far as their abilities in grid-interactive mode. Especially since the Schneider gear is on sale right now from NAWS, I took another look at them, and I think that's what I'm going to go with. What I've primarily been interested in is having a system that can meet my basic electrical needs in an extended outage, secondary is reducing my current electric bill.
The most recent addendum to the manual for the SW reads ...- "AC Support ensures that no current comes from the AC Input connection of the CSW as long as the battery’s state-of-charge (SOC) or battery voltage conditions allow it."
In short, It will do a great job of supplying power if the grid is down during an outage ... BUT ... the SW line will NOT save you much power if connected to the grid for support. Your loads will run mostly on the grid. I have been very disappointed in the Conext SW for this and a few other reasons.
REC TwinPeak 2 285W 3S-3P 2.6kW-STC / 1.9kW-NMOT Array / MN Solar Classic 150 / 2017 Conext SW 4024 Inverter latest firmware / OB PSX-240 Autotransfomer for load balancing / Trojan L16H-AC 435Ah bank 4S connected to Inverter with 7' of 4/0 cable / 24 volt system / Grid-Assist or Backup Solar Generator System Powering 3200Whs Daily / System went Online Oct 2017 / System, Pics and Discussion -
I would never suggest installing a full Hybrid (GT+Off Grid hybrid) AC inverter + battery bank system to save money if you have utility power. So far, when you take the cost of installation and maintenance (new batteries every 5-10 years, new electronics every ~10+ years, etc.), your cost of off grid power is something in the range of ~$1.00 to $2.00+ per kWH (one person here, with hard work and good shopping skills is probably in the $0.50 per kWH range for his off grid system).
With the present costs of utility power and support hardware--I don't foresee such a system saving you money, or even breaking near even.
GT Solar--That can be very cost effective (down towards $0.10 per kWH), and if you have high peak charges ($0.30 to $0.40+ per kWH in California time of use plans), GT solar can save money--But those days are becoming numbered. The utilities and State PUCs are changing the rate plans to where GT Solar is no longer the "money maker" for many people. And it will probably become "worse" as time moves on.
-Bill
Near San Francisco California: 3.5kWatt Grid Tied Solar power system+small backup genset -
I am with Bill unless there is a very specific and known reason. A generator powered by natural or propane is far simpler and requires much less maintenance. I have client who keeps a spare in the factory box that he can take back to costco any time they are open.
The AC support works very well on a CSW if you have large loads and large solar input. The loss from it running in support mode is not a problem if the loads are big during the day.
If you have small loads in daytime support mode, you will be unhappy with either the Outback or Schneiders products."we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
From my experience with the Outback Radian, in Grid Zero mode, it will always draw 80 to 240 watts continuously from the grid while supplying loads from the battery. This about a minimum of 4 kWhs per day. It will take the battery bank down to the Depth of Discharge set point and hold it there until recharging occurs. If higher loads exceed the Depth of Discharge Amps setting, then the grid will supply the extra power needed, whether it is surge or continuous.
In Mini Grid Mode, the Radian will supply loads from the battery bank as if disconnected from the grid. It will continue to supply power from the battery bank until the Mini Grid Connect to Grid volts setting is reached, and then connect to the grid. It will disconnect from the grid upon completion of the next charge cycle. If the load exceeds the capabilities of the inverter while in this mode, then the inverter will shut down with a fault.
In the Summer time I use Grid Zero mode while running loads like AC, and Mini Grid mode mostly for daily loads about 7 months of the year. I am very satisfied with it the way it works . This usage is based on my living in north Florida.
The graphic below is from Opticsre, displaying the system in Grid Zero mode. It is the month of September 2016. Hurricane Hermine knocked out the grid for about 4 days early in the month.
The next is the system mostly in Mini Grid mode during February 2017.
Rick
4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset.
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