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I have been looking at solar for awhile, but in general it did not make sense because my electricity usage is fairly efficient and not in sync with peak insolation. i.e. due to summer tree shading on the west side, I use the least kwh in summer and the most in winter (more lighting and furnace blower), whereas solar PV generates the most in summer and least in winter. However, next week a local solar non-profit is coming to do a site survey - they actually only do households like me who are looking for about a 2-3 kw array to cut down the expensive Tier 3 consumption. If I qualify, the installed price all in before federal incentives will run about $3/watt.
Now what I'm trying to calculate is how much I can save each year to shorten my payback period. Can anyone validate my assumptions about PG&E's E-6 TOU rate, which is not only TOU but also very confusingly tiered? Basically I understand the strategy is to try to bank excess generation credits during summer (where there is net generation at peak rates), and apply those credits during other periods of net usage at off-peak. What I'm confused about is how baselines are allocated across peak, partial-peak, and off-peak, and thus whether I'm banking excess generation at peak Tier 1 ($0.26/kwh) or peak Tier 3 ($0.44/kwh), which is a fairly big difference.
Assumption 1: PG&E meter can only measure net usage or generation, cannot measure solar generation separately from household usage.
If this is true, then I've calculated that on a typical summer day I'll have net usage of
Off-peak 10 kwh
Partial peak 0 kwh (solar offsets consumption)
Peak -5 kwh (net generation)
Assumption 2: PG&E baseline is pro-rated across the three periods, using absolute values. This is the confusing part.
My summer baseline is about 10 kwh per day. PG&E will add 10 + 0 + |-5| = 15 kwh, and then pro-rate baseline as:
Off-peak 6.7 kwh
Partial peak 0 kwh
Peak 3.3 kwh
Therefore in summer I'll my off-peak will push slightly into Tier 2 or even Tier 3, while my peak generation will be primarily Tier 1 & 2.
Assumption 3: The generation credits will be at the prevailing Tiered rate.
So basically the net generation in summer during peak hours will be about 3.3 kwh at Tier 1 rates of only $0.26/kwh.
Assumption 4: As a higher winter user, any winter solar generation is offsetting Tier 3 rates.
Maximum generation in winter might only be 5 kwh per day, whereas I use 20 kwh per day, so it's all offsetting Tier 3 consumption, which at off-peak and pp rates is $0.27-28/kwh.
So if these are correct, then an hour banked of peak summer Tier 1 at $0.26 is offsetting about one hour of off-peak winter Tier 3 at $0.27-28.
Basically my unique situation is that I can't get the maximum summer generation from the panels because the late afternoon sun is shaded by west trees. I'll still be a net generator in summer peak, but not to bank any credits at peak Tier 3 ($0.44). So it seems that I might not want to optimize tilt and direction for summer peak, but may want to optimize for winter and shoulder-season off-peak (e.g. capture more morning sun to the east), because even off-peak Tier 3 is saving $0.27-0.28?
Now what I'm trying to calculate is how much I can save each year to shorten my payback period. Can anyone validate my assumptions about PG&E's E-6 TOU rate, which is not only TOU but also very confusingly tiered? Basically I understand the strategy is to try to bank excess generation credits during summer (where there is net generation at peak rates), and apply those credits during other periods of net usage at off-peak. What I'm confused about is how baselines are allocated across peak, partial-peak, and off-peak, and thus whether I'm banking excess generation at peak Tier 1 ($0.26/kwh) or peak Tier 3 ($0.44/kwh), which is a fairly big difference.
Assumption 1: PG&E meter can only measure net usage or generation, cannot measure solar generation separately from household usage.
If this is true, then I've calculated that on a typical summer day I'll have net usage of
Off-peak 10 kwh
Partial peak 0 kwh (solar offsets consumption)
Peak -5 kwh (net generation)
Assumption 2: PG&E baseline is pro-rated across the three periods, using absolute values. This is the confusing part.
My summer baseline is about 10 kwh per day. PG&E will add 10 + 0 + |-5| = 15 kwh, and then pro-rate baseline as:
Off-peak 6.7 kwh
Partial peak 0 kwh
Peak 3.3 kwh
Therefore in summer I'll my off-peak will push slightly into Tier 2 or even Tier 3, while my peak generation will be primarily Tier 1 & 2.
Assumption 3: The generation credits will be at the prevailing Tiered rate.
So basically the net generation in summer during peak hours will be about 3.3 kwh at Tier 1 rates of only $0.26/kwh.
Assumption 4: As a higher winter user, any winter solar generation is offsetting Tier 3 rates.
Maximum generation in winter might only be 5 kwh per day, whereas I use 20 kwh per day, so it's all offsetting Tier 3 consumption, which at off-peak and pp rates is $0.27-28/kwh.
So if these are correct, then an hour banked of peak summer Tier 1 at $0.26 is offsetting about one hour of off-peak winter Tier 3 at $0.27-28.
Basically my unique situation is that I can't get the maximum summer generation from the panels because the late afternoon sun is shaded by west trees. I'll still be a net generator in summer peak, but not to bank any credits at peak Tier 3 ($0.44). So it seems that I might not want to optimize tilt and direction for summer peak, but may want to optimize for winter and shoulder-season off-peak (e.g. capture more morning sun to the east), because even off-peak Tier 3 is saving $0.27-0.28?
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