TDSF Power Plant: Year 5 report

At the end of year five the meter reading was 98767, meaning we have produced about 1240 KWh more than we consumed over the past 5 years. The first three years we were slightly in the hole, as the meter read 00387, so the gain has come in the last two years. At the end of year four it was 99602 so we came out ahead by 835 KWh this year.

What is surprising about this is that this was our lowest year of production yet, producing a rounding error less than 9 MWh, whereas the first four years we did a little better than 9 MWh. We generated our 46th MWh on March 20.

Is this because the panels are losing their production capacity? Probably a little bit. They are guaranteed not to lose more than 1/2% per year after the first year. However, weather probably plays a factor as well. This past summer we were impacted by smoke from Canadian wildfires. This past February we had two back-to-back snows with freezing temperatures, so the panels produced no power for about 10 days. Just adding what would have been 80 kilowatt hours over that period back into our totals would be enough to get back over the 9 MWh mark.

We had built up enough surplus over the summer and fall that I was sure we would cover the winter deficit. We did cover through January, but the 10 day February shortfall used up the surplus and left us with a small bill (about $22) for that month. Fortunately, we are back in surplus again in March.

As a review, the way our billing works, the March/April bills produce a large surplus (days are longer, sun is higher, no AC) but this gets zeroed out at the end of the April billing period and we get a check in May for the supplier portion of this surplus. The utility keeps the delivery portion.

(Incidentally, the delivery portion has roughly doubled recently, from 2.5 cents to about 5 cents per KWh so electricity now costs about 16 cents per KWh – it was about 10.7 cents early in our journey).

This means we resume building a surplus to carry us through the winter (October – February) starting in May.

I sometimes get asked about the ‘payoff date.’ This is the amount of time until the savings from not paying an electric bill equals the cost of the system. Honestly, I don’t know when that will be as one factor is the current cost of electricity. As that increases, now up about 50% from when we went operational, that date shrinks.

I have rather focused on what the cost of electricity will be for us over the 25 year guaranteed life of the panels. By the way, they keep producing electricity in year 26!

Assuming our panels generate at least 200 MWh over the 25 year period (which seems conservative, as they have generated 46 MWh in the first five years) and assuming the SREC market supports a price of $50/MWh (this is not guaranteed at all – it is currently about $4/SREC in Ohio and over $300 in New Jersey and DC), and that our March/April surplus averages about $60/year, the total cost of the power our panels will generate will have cost us about 2-4 cents per KWh. That is a good deal.

Of course we will have to pay market rates for anything we consume above what the panels generate, but that is to be expected. As of now though, our electricity use continues to decline, as evidenced by the meter continuing to run backward, compared to the same month of the prior year. Should we get an EV sometime in the future, or convert our heat and hot water to electricity this will of course change.

Whether solar panels are a good deal are very much dependent on site location, federal and local $$ help with the project and whether there is something like an SREC market. For this project specifically, it seems to be a great deal.

Here is the comparative overview of the past 5 years on a monthly basis:

TDSF Power Plant: Year 3 Was a Great Year!

In my Year 2 Report, I mentioned that we would have needed 2 more panels to generate more electricity than we consumed. That’s because the meter reading at the end of year 2 (March 26, 2021 at 1:30 PM) was 01098 and our worst panel had produced about 257 KWh/year.

What a difference a year makes. On March 26, 2022 the meter reading was 00387. This means we consumed 712 KWh less than we produced this year (1098 – 387). The 3 year reading for our worst panel was 778.2 KWh. So one more panel that was at least as good as our poorest producing panel would have put is in the black (the meter reading would have been negative).

Does this mean we produced 712 KWh more this year than last year? No. Here are the meter readings and total production for the first 3 years:

Meter ReadingAnnual TotalCumulative Total
04559.679.67
010989.118.77
003879.3328.1
First 3 years of production

We produced a little more in year 3 than in year 2 (230 KWh), but the main reason for the improvement was a reduction in consumption (482 KWh). This reduction allowed us to build up a greater surplus going into the winter months so that we only had an electric bill for two months of the year, for a total of 200 KWh. The only reason we had these two bills at all is because BGE, our utility company, zeroes out the surplus after the April reading and sends us a check for the surplus supply amount we generate each March and April. This means we do not have enough credits by the end of the winter and so we have to pay for what we do not produce those last few months.

As you may recall from previous posts, the electric bill is divided into supply and delivery (and smaller amount for the meter charge and taxes). The delivery amount is about 3.5 cents per KWh.

DateKWhRate (Supply)Check Amount
5/20/20194460.087939.20
5/22/20205350.08280944.30
5/24/20219130.07144665.23
Total1894148.73
Payment for March/April Surplus

I will not get a check for this year’s surplus until late May, but using .08 per KWh as an estimate for the supply rate and 300 KWh for the March surplus (300 * .08 = $24), we can guess that the total March/April surplus by the end of year 3 is about $173.

The $24 amount is interesting for the March surplus, as the cost for the 200 KWh that we got charged for in January and February (due to the zeroing out the previous March) was approximately $24 as well. If BGE did not zero out the surplus each year we would have essentially had no electric bill this year, except for the (approximately) $100 per year they charge for the meter (labeled as a customer charge).

Looking at this over the 3 year period, we used 129 KWh more per year (averaged out) than we consumed. This is calculated by dividing the meter reading (00387) at the end of year 3 by 3. Rounding a bit, using 0.12 per KWh or $120 per MWh, in theory we should have paid on average $15.48 per year, or $46.44 total over three years. In fact, because we are not compensated for the delivery portion of the March/April surplus, we paid more. Following is the approximate reconciliation:

AmountComments
Amount paid $595What we sent BGE over 3 years
Meter charge$300Approximate (varied from $8.22 – 8.75/month)
Net paid for electricity$295$595 – 295
Surplus BGE paid us for$173includes guess for March 2022
Actual bill for electricity$122$295 – 173
Delivery not reimbursed$77Approximate using .035 per KWh
Net should have paid$45
Reconciliation of what we should have paid vs actual based on meter reading

So the amount we should have paid reconciles with the amount we actually paid. Effectively, the March/April surplus zero-out cost us an additional $2.14 per month.

How did we reduce consumption by almost 1/2 MWh? I’m not sure. Some of it was intentional. We found a few more bulbs to convert to LED. We set our thermostats a little differently, focusing on comfort at the end of the house we were in and reducing/increasing the setting at the other end. We took a couple of short trips, 3-5 days each and set the thermostat higher while we were gone. Finally, my wife required more sleep this year due to her health, and so she was generating less electricity while sleeping. I expected we would use less over time as we got older and as appliances got more efficient, but we have not replaced anything yet.

I have noted previously that the amount of solar energy we convert to electricity is highly dependent on how cloudy/rainy it is. Panels theoretically degrade slightly as the year goes on. However, we can see from this snapshot that more recent quarters sometimes produced more electricity than older quarters.

One last picture, to show that we had surpluses (or accumulated surpluses to zero out our bill in every month this past year but two:

One last note. As our annual production was over 9 MWh each year, we produced our 28th SREC on March 22, 4 days before the end of year 3.

Please respond with any comments or questions. I enjoy helping people decide if solar panels are a good opportunity.

TDSF Power Plant Part 10: 9 Month Update

Got an electric bill again

(This is the latest in an on-going series. Here is Part 1).

As 2019 wraps up, I have some good news and some not-so-good news to report.

First, the good news: in November we got paid $213.32 for the 4 SRECs we generated in the 3rd quarter (July – Sep). These were SRECs 4 – 7. (1 SREC = 1 Megawatt Hour of electricity generated. )

Now, the not-so-good news: in the 4th quarter (Oct – Dec), production dropped off drastically. It took us until Dec 21, 84 days, to generate our 8th SREC.

Megawatt (SREC) History
DateMWhDaysCumulative
3/26/20190
4/21/201912727
5/21/201923057
6/14/201932481
7/6/2019422103
7/30/2019524127
8/26/2019627154
9/28/2019733187
12/21/2019884271

From the table above, you can see that the time to generate each of the first 7 SRECs ranged from 22 to 33 days. Comparatively speaking, that 8th SREC took forever.

So, what happened? As mentioned in Part 9, the sun got much lower in the sky and the days got shorter. The oak trees on the south side of my house (some of which are in my neighbor’s yard) did not drop their leaves until early December. Finally, we had a lot of cloudy days. These factors all combined to lower power production greatly. Shown below in picture form:

Through the end of September’s billing period, we had built up a surplus of almost 600 KWh. By the end of November’s billing period we had used it all up, and then some. We owed our electric company about $5 above the $8.22 charge for the meter. So in December, we were billed for all of the electricity we used, less the 255 KWh that we generated. See the chart:

Date DueBilling PeriodCurrent ReadingPrevious ReadingMetered UsageCarryover AppliedAccrued CarryoverAmount Owed
5/20/20193/26 – 4/249956612-4460-4468.26
6/20/20194/24 – 5/239926599566-3000-3008.26
7/24/20195/23 – 6/269897199265-2950-5958.22
22-Aug6/26 – 7/2698982989711111-5848.22
9/23/20197/26 – 8/2699009989822727-5578.22
10/21/20198/26 – 9/259896799009-420-5998.22
11/22/20199/25 – 10/289926298967295295-3048.22
12/19/201910/28 – 11/259960899262346304013.21
1/22/202011/25 – 12/2783996084750065.86

In picture form, here is our electricity usage (from our utility) – solar panels went live 3/26. Our billing cycle begins about the 26th of each month (varies slightly).

Agreeing with the Judy Collins’ song, I really don’t like clouds, at all. Here is what cloudy/rainy days in December look like compared to more normal days:

The really short lines around the 1st and the 15th of the month (and a few others) are examples of very low production on cloudy/rainy days. On good days in December, production tops 10 KWh. Compare that to the summer months, where a good day produces over 50 KWh. Big difference!

So what is the take away from this post? When we went live on March 26 our meter read 00012. When they read the meter for our Dec 27 billing, it read 00083. So in 9 months, we have used a net 71 KWh from our utility. In other words we have produced all of the electricity we need to run our house from our solar panels over this 9 month period, less about 3 days. Not too shabby.

As the days get longer and the sun gets higher, here are my predictions for the next 3 months:

  • January we will still be in the red, using more than we produce, but less than December. I am hoping we cut the December overage (475 KWh) in half.
  • February we will do even better, and I hope we cut the overage in half again.
  • That would mean we get billed for about 240 KWh in January and 120 KWh in February, or 360 KWh total.
  • In March I expect we will generate a surplus.

I will let you know how it turned out in future posts.

If you enjoy reading these updates, please drop me a note. I will be happy to respond to questions as well.

TDSF Power Plant Part 7: What is the Social Utility of Going Solar?

Googling ‘social benefits of solar power’ or something similar retrieves a large number of solar company articles talking about things like local jobs, less pollution, less fossil fuel generation, blah, blah, blah.

While there may be some truth to this, mostly it is an appeal to the tree-hugger in you to entice you to sign a contract.

To be clear, as outlined in previous posts, we installed our panels to help ourselves. We are lowering future budgeted costs to reduce the amount spent from drawing down retirement savings on these costs, perhaps if we so choose, to spend them on something else. When was the last time you heard someone express joy upon paying their electric bill?

This is nothing more than the invisible hand at work. However, as with most tax policy, the government has deemed it socially desirable to reward higher earning taxpayers for doing something they feel benfits society, in exchange for reducing their taxes. In effect, the government has added a few fingers to the invisible hand.

The combined Federal, State, and County purchase incentives account for over 42% of the purchase price for the system we bought. The combination of electric bill reduction to near zero (about $100 a year for the meter) plus the potential for $600 – $800 per year in income for the next 25 years, justifies the purchase in and of itself.

About that $600-800 number. This comes from estimating our production overage at 2 MWh per year (worth about $176 at today’s rates) plus the current SREC rate of about $50 per MWh * 12 MWh output estimated per year generates this yet to be proven number. Note that all items here are variables subject to change, so the cash flow is also likely to be volatile.

When I first started journaling this effort, SRECs were only worth about $15 each after brokerage fees. The Maryland legislature has since mandated an increase in renewable energy incrementally over the next decade or so, including an increasing amount from solar. The day the legislation passed, the SREC market in Maryland jumped to $55 ($50 net to owners after the brokerage fee). We will probably generate about 12 MWh per year.

Spelling that out:

SRECs: 12*$50 = $600
Excess Power = 2 MWh * $88/MWh = $176
$600 + $176 = $776

SRECs trade in a marketplace subject to supply and demand. The utility companies buy SRECs in lieu of producing their own solar power – this is the demand. The supply of course are the rooftops (and any solar farms communities might deploy). If this legislation results in a large increase in deployed solar panels in Maryland the market price of SRECs will drop accordingly.

The paragraphs above explain how the government is incentivizing high earning taxpayers to install solar. That does not really answer the original question, what is the social utility of going solar – it just describes the economic price the various government units are willing to pay.

To understand the benefit to society in real terms, understand this very important fact about electricity – it is used immediately upon generation.

You may read about some battery storage systems in Australia or some water pumping schemes to move water uphill when demand and rates are low and flow it through generators when rates are high.

These storage or time of day arbitrage efforts are real but to date represent a small percentage of electricity generation. For the most part, as of today, electricity is generated and used. Or not. If the electricity is generated and not used it is for the most part wasted.

To complete the thought we will use a traffic analogy. Picture any of the various loops (beltways) that surround many of our cities. They may be 6 lane in some places, 8 lanes in others, maybe even more in some larger cities. No matter how wide they are, there is still a time of day when traffic is very dense and moves very slowly.

There is typically other times of the day (or weekends and holidays) when these roads are under used. An accident can realy mess things up, especially at rush hour. (Why do they call it rush hour anyway? – no one is moving very quickly – an oxymoron if there ever was one!)

It is impossible to build these roads to perfectly accomodate demand. Some highways are adding time of use tolls, HOV lanes and reversible lanes to accomodate and/or shape demand. These can help, but there are limits to what they can accomplish.

Electric utilities have their own time of day usage patterns. Demand rises as people rise in the morning, levels off as they go to work, increases again when they get home, and lowers greatly when everyone goes to bed.

Just as it would be economically and practically foolish/difficult to build enough highway capacity for the worst rush hour traffic, it is similarly economically and practically foolish/difficult for the electric company to build enough capacity to satisfy the highest demand.

Electricity plants (whatever their source) are expensive. So is electricity storage – maybe that will change but it is true today. So building enough to supply at the highest demand results in either:

  1. generation of electricity that is wasted when no one wants it, or
  2. building plants that sit idle much of the time.

Neither option is smart.

Instead, utilities generate enough of their own power to satisfy some reasonable amount of demand and then buy the rest of the electricity from external suppliers as needed. This is known as the spot market.

Spot prices can vary – as mentioned above, unused electricity is wasted. So when the larger market (beyond the local utility) is not demanding much electricity from external suppliers, the spot market is inexpensive.

Given all of this information, here are some ways that rooftop solar systems help utilities and their neighbors:

  • to the extent we are using our own electricity at times of high demand, the utility has that much less it needs to supply and therefore that much less it needs to buy on the spot market at high prices.
  • if we are generating more electricity than we need at times of high demand we are effectively supplying our neighbors with our surplus, as it goes back through the net-meter, reducing the amount utilties may have to buy fromthe spot market.
  • to some extent, these first two factors must be reducing the load on the wires from the nearest substation to our neighborhood, hopefully reducing the likliehood of transformers or other components failing.
  • to some extent, these first two factors are also reducing the likelihood of brownouts and blackouts, assuming they reduce the peak demand on transmission components.
  • in some markets the utilities can sell excess capacity to the spot market and will do so when the spot market is buying for a price higher than what they sell it their customers. So the electricity generated by rooftop solar frees up additional capacity for them to sell. This helps the utility make more money, which benefits its shareholders, but should have some impact on keeping rate hikes for customers down, either by amount or by frequency.

This line of reasoning supports something we did not do, but something utilities should encourage: installing panels on the west side of a house. One counter-argument to my reasoning above is that solar panels produce less as the sun is setting, when demand is rising. This is of course specific to certain times of the year.

If the sun is not setting until 8:30 or later, this is past the surge point, although to be fair, solar power is dropping off for me at 5 PM, though it continues at a lower rate until close to sunset.

There are two factors at play in our situation:

  1. no west facing panels
  2. generation 1 solar system – we have a large tree on the west side of our house that is close enough and large enough to provide the original solar power – shade, and lots of it. So as we pass 5 PM the ever lengthening shadows cover not only the west side of my house, but the southern roof where my panels are.

During times other than the peak summer days, when leaves are not on this tree and the sun sets more to the southwest, we are still providing power when people come home from work and at a minimum, we are not contributing much, if anything to the increase in demand.

In summary, install solar if you benefit economically from it. If enough people make this selfish decision, the community as a whole will benefit. All the other arguments about fossil fuel reduction, cleaner air, etc. are nice, but are not germane to helping you achieve your financial goals.