Detailed DC system design
Design will be completed in January 2021
Location: Pampachiri, Apurimac, Peru
GPS coordinates: 14°11'37.65"S 73°32'31.73"W
Altitude: 3378m
Description: A two story adobe home in the Peruvian Andes with only DC power needs.
Contents
- 1 Load evaluation
- 2 Weather and solar resource evaluation
- 3 Load and solar resource comparison
- 4 Design parameters
- 5 Energy storage sizing and selection
- 6 Minimum PV source size
- 7 PWM charge controller sizing and selection
- 7.1 Step 1: Determine PV module power rating
- 7.2 Step 2: Determine proposed module configuration
- 7.3 Step 3: Verify excess production
- 7.4 Step 4: Verify charging current
- 7.5 Step 5: Determine final number of PV modules
- 7.6 Step 6: Total PV source current
- 7.7 Step 7: Select a charge controller
- 7.8 Step 8: Determine final PV source power rating
- 8 Wire, overcurrent protection, and disconnect sizing and selection
- 8.1 PV source circuit
- 8.1.1 Phase 1: Maximum circuit current
- 8.1.2 Phase 2: Wire ampacity
- 8.1.3 Phase 3: Overcurrent protection and disconnects
- 8.1.4 Phase 4: Voltage drop
- 8.1.5 Phase 5: Terminal temperature ratings
- 8.1.6 Step 1: Maximum ampacity based upon terminal temperature rating
- 8.1.7 Step 2: Verify OCPD protection of terminals
- 8.1 PV source circuit
- 9 Notes/references
Load evaluation
Step 1: Fill out DC load chart
April - September | October - March | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
# | Load | Quantity | Watts | Total watts | Duty cycle | Hours per day | Days per week | Average daily DC watt-hours | Hours per day | Days per week | Average daily DC watt-hours |
1 | 5 W LED | 6 | 5 W | 30 W | 1 | 3 hours | 7 days | 90 Wh | 3 hours | 7 days | 90 Wh |
2 | Radio | 6 W | 1 | 6 W | 1 | 5 hours | 7 days | 30 Wh | 5 hours | 7 days | 30 Wh |
3 | Cell phone | 10 W | 2 | 29 W | 1 | 1 hours | 7 days | 20 Wh | 1 hours | 7 days | 20 Wh |
- Load: The make and model or type of load.
- Quantity: The number of the particular load.
- Watts: The power rating in watts of the load.
- Total watts = Quantity × Watts
- Duty cycle = Rated or estimated duty cycle for the load. If the load has no duty cycle a value of 1 should be used. A load with a duty cycle of 20% would be inputted as .2
- Hours per day: The maximum number of hours the load(s) will be operated per day. If the load has a duty cycle 24 hours should be used.
- Days per week: The maximum number of days the load(s) will be operated per week.
- Average daily DC watt-hours = Total watts × Duty cycle × Hours per day × Days per week ÷ 7 days
Step 2: Determine DC energy demand
Total average daily DC watt-hours (April - September) | = sum of Average daily DC watt-hours for all loads for April - September |
---|---|
= 140 Wh |
Total average daily DC watt-hours (October - March) | = sum of Average daily DC watt-hours for all loads for October - March |
---|---|
= 140 Wh |
Total average daily energy demand
The total energy demand for the system is the added Average daily DC-watt hours and Average daily AC watt-hours for each time period.
Average daily watt-hours required (April - September) | = Total average daily DC watt-hours (April - October) + Total average daily AC watt-hours (April - September) |
---|---|
= 140 Wh |
Average daily watt-hours required (April - September) | = Total average daily DC watt-hours (October - March) + Total average daily AC watt-hours (October - March) |
---|---|
= 140 Wh |
Weather and solar resource evaluation
Maximum ambient temperature = 23°C
Minimum ambient temperature = 2°C
Maximum indoor temperature = 20°C
Minimum indoor temperature = 10°C
Load and solar resource comparison
Step 1: Determine monthly ratio of energy demand to solar resource
Month | Average monthly insolation | Total average daily energy demand | Ratio |
---|---|---|---|
January | 193.85 kWh/m² | 140 Wh | .722 |
February | 162.2 kWh/m² | 140 Wh | .86 |
March | 179.81 kWh/m² | 140 Wh | .78 |
April | 174.98 kWh/m² | 140 Wh | .8 |
May | 214.31 kWh/m² | 140 Wh | .65 |
June | 200.05 kWh/m² | 140 Wh | .7 |
July | 210.35 kWh/m² | 140 Wh | .67 |
August | 229.96 kWh/m² | 140 Wh | .61 |
September | 126.87 kWh/m² | 140 Wh | 1.1 |
October | 214.82 kWh/m² | 140 Wh | .65 |
November | 212.91 kWh/m² | 140 Wh | .66 |
December | 176.98 kWh/m² | 140 Wh | .79 |
- Month: The month of the year.
- Average monthly insolation: Solar resource data obtained for the location from Weather and solar resource data sources.
- Total average daily energy demand for the month from the load evaluation.
- Ratio = Total average daily energy demand ÷ Average monthly insolation
Step 2: Determine design values
Design daily insolation | = Average monthly insolation from month with the highest ratio ÷ 30 |
---|---|
= 126.87 kWh/m² ÷ 30 = 4.23 kWh/m² |
Design daily watt-hours required | = Total average daily energy demand from month with the highest ratio |
---|---|
= 140 Wh |
Design parameters
System voltage parameter = 12 V
- The system, based upon the load evaluation, will be relatively small. A 12 V system makes the most sense.
Irradiance safety parameter = 1.25
- The irradiance safety parameter is always the same.
Continuous duty safety parameter = 1.25
- The continuous duty safety parameter is always the same.
Low voltage disconnect parameter = 11.5 V
- A simple charge controller with a pre-programmed low voltage disconnect will be used.
Energy storage sizing and selection
Step 1: Determine depth of discharge parameter
For this project a depth of discharge of .5 (40%) is a good compromise.
- Depth of discharge = .5
Step 2: Determine days of autonomy parameter
The home is used daily and providing lighting is very important, but at the same time the budget for the project is limited. The users are willing to adjust their consumption during periods of poor weather according to the state of charge of the energy storage system.
- Days of autonomy = 2
Step 3: Determine battery temperature correction factor
The minimum indoor temperature was determined to be 10°C. An AGM battery will be used to avoid regular maintenance.
- Battery temperature correction factor = 1.08
Correction factors for various battery types:[1]
Temperature | FLA | AGM | Gel |
---|---|---|---|
25°C | 1.00 | 1.00 | 1.00 |
20°C | 1.06 | 1.03 | 1.04 |
15°C | 1.13 | 1.05 | 1.07 |
10°C | 1.19 | 1.08 | 1.11 |
5°C | 1.29 | 1.14 | 1.18 |
0°C | 1.39 | 1.20 | 1.25 |
-5°C | 1.55 | 1.28 | 1.34 |
-10°C | 1.70 | 1.35 | 1.42 |
Step 4: Calculate total Ah required
Total Ah required | = Average daily Watt-hours required ÷ System voltage parameter × Battery temperature correction factor (step 3) × Days of autonomy parameter (Step 2) ÷ Depth of discharge parameter (Step 1) |
---|---|
= 140 Wh ÷ 12 V × 1.08 × 2 days ÷ .4 = 43 Ah |
Step 5: Calculate number of batteries in series
A 12 V battery is ideal for a system of this size.
Batteries in series | = System voltage parameter ÷ Chosen battery voltage |
---|---|
= 12 V ÷ 12 V | |
= 1 × 12 V battery is sufficient |
Step 6: Calculate number of batteries in parallel
In Peru 12 V AGM batteries are widely available in 40 Ah, 55 Ah and 75 Ah sizes. 55 Ah is too small, so a 75 Ah battery will have to be used.
Batteries in parallel | = Total Ah required (step 4) ÷ Chosen battery Ah rating |
---|---|
= 43 Ah ÷ 55 Ah = .78 | |
= Round up to 1 × 55 Ah battery. |
https://www.mkbattery.com/application/files/2715/6158/6466/8A22NF-DEKA_Spec_Sheet.pdf
Step 7: Calculate final Ah capacity
Final Ah capacity | = Number of batteries in parallel (Step 7) × Chosen battery Ah rating |
---|---|
= 1 battery in parallel × 55 Ah = 55Ah |
Minimum PV source size
Step 1: Deteremine PV source loss parameters
The PV module(s) will be mounted on a pole mount system.
- Module degradation parameter = .94
- Shading loss parameter = .95
- Soiling loss parameter = .97
- Wiring loss parameter = .96
- Module mismatch parameter = 1
- Mounting system temperature adder = 20°C for a pole mount
- PV source temperature loss parameter = -.48%/°C
PV source temperature loss parameter = 1 + (Maximum ambient temperature + Mounting system temperature adder - 25°C) x Temperature coefficient of max power %/°C ÷ 100 = 1 + (23°C + 20°C - 25°C) x -.48%/°C ÷ 100 = .91
Total PV source loss parameter = Module degradation parameter × Shading loss parameter × Soiling loss parameter × Wiring loss parameter × Module mismatch parameter × PV source temperature loss parameter = .94 × .95 × .97 × .96 × 1 × .91 = .76
Step 2: Charge controller efficiency parameter
All charge controllers lose a certain percentage of all energy that is produced as heat as it is transferred to the energy storage system and loads. For both PWM and MPPT charge controllers a value of .98 (98% efficient) can be used.
Step 3: Energy storage efficiency parameter
The system will use an AGM battery, which is a VRLA battery.
- Valve-regulated lead acid (VRLA) battery efficiency = .85 (85% efficient)
Step 4: Deteremine minimum size of the PV source
Minimum PV source size | = Design daily watt-hours required ÷ Design daily insolation ÷ Total PV source loss parameter (Step 1) ÷ Charge controller efficiency parameter (Step 2) ÷ Energy storage efficiency parameter (Step 3) |
---|---|
= 140 Wh ÷ 4.23 kWh/m² ÷ .76 ÷ .98 ÷ .85 = 52 W |
Step 5: Determine charge controller type
A PWM charge controller is a reliable, low-cost option for a small system like this.
PWM charge controller sizing and selection
Step 1: Determine PV module power rating
The chosen System voltage limits the choices of modules and configurations that are possible with a PWM charge controller. A 12 volt system requires 1 ×36-cell module per string. The minimum size was determined to be 52 W. A 80 W polycrystalline PV module will be used for the design.
PV module power rating | = 80 W |
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Number of modules in series | = 1 module |
---|
Step 2: Determine proposed module configuration
This calculation will give a minimum number of PV modules - the result should always be rounded up. Different modules sizes and configurations can be explored to find the optimal design.
Minimum number of PV modules | = Minimum PV source size ÷ PV module power rating (Step 1) |
---|---|
= 52 W ÷ 80 W = .65 | |
= 1 × 80 W module. |
Minimum number of modules in parallel | = Minimum number of PV modules ÷ Number of modules in series (Step 1) |
---|---|
= 1 ÷ 1 = 1 |
Step 3: Verify excess production
Proposed PV source low insolation production | = PV module power rating (Step 1) × Minimum number of PV modules (Step 2) × Total PV source loss parameter × Design daily insolation × Charge controller efficiency parameter × Energy storage efficiency parameter |
---|---|
= 80 W × 1 × .76 × 4.23 kWh/m² × .98 × .85 = 214 Wh |
Daily excess production in Ah | = (Proposed PV source low insolation production - Design daily watt-hours required) ÷ System voltage parameter |
---|---|
= (214 Wh - 140 Wh) ÷ 12 volts = 6.2 Ah |
Ah used at full depth of discharge | = Final Ah capacity × Depth of discharge parameter |
---|---|
= 55Ah × .5 = 27.5 Ah |
Time to reach full state of charge | = Ah used at full depth of discharge ÷ Daily excess production in Ah |
---|---|
= 27.5 Ah ÷ 6.2 Ah = 4.4 days |
The battery will be able to reach full state of charge while using loads in 4.4 days, which is less than the maximum of 7 days. The design is okay.
Step 4: Verify charging current
This system will use an AGM battery, so its charge current should be between .05 (5%) and .2 (20%) of its C/20 rating.
Minimum required charge current | = Final Ah capacity × .05 |
---|---|
= 55 Ah × .05 = 2.75 A |
It is necessary to check the minimum required charge current against the available charge current from the proposed PV source power rating.
Available charging current | = Maximum power current (Imp) × Minimum number of PV modules in parallel |
---|---|
= 4.4 A × 1 = 4.4 A |
Percentage of C/20 rate | = Available charging current ÷ Final Ah capacity |
---|---|
= 4.4 A ÷ 55 Ah = .08 |
The PV source can supply .08 (8%) of the C/20 current rating of the energy storage system, which is more than .05 (5%) and less than .2 (20%). The PV source configuration is okay.
Step 5: Determine final number of PV modules
Determine a final number of modules and a series/parallel configuration that can meet the requirements of Step 1, Step 2, Step 3, and Step 4.
Final number of PV modules | = 1 |
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Final number of PV modules in series | = 1 |
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Final number of PV modules in parallel | = 1 |
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Step 6: Total PV source current
This calculation will give a minimum current rating to use as a basis for selecting the charge controller. The Isc rating of the PV module can be found on its specifications sheet.
Total PV source current | = Final number of PV modules (Step 5) × Isc rating of chosen module (Step 1) × Irradiance safety parameter |
---|---|
= 1 × 4.85 A × 1.25 = 6.1 A |
Step 7: Select a charge controller
The final chosen charge controller should:
- Function at the system voltage.
- The charge controller(s) should have a total current rating that is larger than the minimum current rating (Step 6).
The result of the following equation should always be rounded up.
Number of charge controllers | = Total PV source current (Step 6) ÷ Chosen charge controller current rating |
---|---|
= 6.1 A ÷ 10 A = .61 = 1 (rounded up to 1 charge controller) |
Step 8: Determine final PV source power rating
PV source power rating | = PV module power rating (Step 1) × Final number of PV modules in parallel (Step 5) |
---|---|
= 80 W × 1 = 80 W |
Wire, overcurrent protection, and disconnect sizing and selection
PV source circuit
If a wire size meets the current requirements determined in Phase 2 but fails to meet either the overcurrent protection requirements in Phase 3 or the voltage drop requirements in Phase 4, then the wire size will have to be increased.
Phase 1: Maximum circuit current
Maximum circuit current | = PV module Isc × Irradiance safety parameter |
---|---|
= 4.85 A × 1.25 = 6.1 A |
Phase 2: Wire ampacity
There will only be two current-carrying conductors in the conduit. The maximum ambient temperature 23°C. 90°C rated PV wire will be used for this circuit.
The minimum wire size for a circuit can be using the following steps:
- Determine the ambient temperature correction factor based upon the maximum ambient temperature using the Ambient temperature correction factor table. The ambient temperature correction factor for this circuit is 1.08 because it is a 90°C rated wire with a maximum ambient temperature of 23°C.
- Determine the conduit fill correction factor based upon the number of number of conductors in the conduit using the Conduit fill correction factor table There will only be two current-carrying conductors in the conduit, so the conduit correction fill factor is 1.
- Determine the total wire correction parameter based upon the smaller of: the Ambient temperature correction multiplied by the Conduit fill correction factor or .8 (a safety factor from the US National Electrical code).
- Determine minimum wire ampacity. Divide the maximum circuit current (Phase 1) by the total wire correction factor (Step 3)
- Select a wire size with a maximum rated ampacity equal to or above the minimum wire ampacity calculated in the previous step using the allowable wire ampacity table. A 4 mm² PV wire with an ampacity rating of 30 A at 90°C will be used for this circuit as this is a commonly used wire type and size for a circuit of this type. 30 A provides far more ampacity than the required 7.6 A.
Total wire correction parameter | = Smaller of (Ambient temperature correction factor × Conduit fill correction factor) or .8 |
---|---|
= Smaller of (1.04 × 1) or .8 = .8 |
Minimum wire ampacity | = Maximum circuit current (Phase 1) ÷ Total wire correction parameter (Step 3) |
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= 6.1 A ÷ .8 = 7.6 A |
Phase 3: Overcurrent protection and disconnects
This circuit, since it only has 1 PV module, does not require an OCPD, but one will be located near the PV equipment to provide a PV power source disconnect.
The appropriate overcurrent protection device size can be determined by:
- Determine the minimum size
- A standard 10 A DC breaker will be used. This is breaker is larger than the required minimum OCPD size, but far smaller than the rated ampacity of the wire that it will protect.
- Verify that the chosen OCPD size from Step 2 will protect the wire size chosen in Phase 2 from excessive current under the conditions of use. The current rating of the chosen breaker size (Step 2) must be less than the calculated maximum current under conditions of use unless the calculated maximum current under conditions of use is between standard OCPD values, in this case the next largest breaker can be chosen.
Maximum current under conditions of use = Wire ampacity from allowable wire ampacity table × Total wire correction parameter (Phase 2). = 30 A × .8 = 24 A Verify OCPD under conditions of use = Maximum current under conditions of use must be greater than the current rating of the chosen OCPD (Step 2) = 24 A is greater than 10 A.
Minimum OCPD size | = Maximum circuit current (Phase 1) × 1.25 |
---|---|
= 7.6 A × 1.25 = 9.5 A |
The OCPD size is okay.
Phase 4: Voltage drop
If the voltage drop for the wire chosen in Phase 2 for a particular circuit is not within the recommended values, then using a larger sized wire should be considered. Increasing the wire size will not affect any other part of this process; the calculated OCPD size can remain the same.
This circuit will be 6 meters long one-way. It is 4 mm² wire with a resistance value in (Ω/Km) of 6.73 Ω. We would like to keep the voltage drop between the PV source and the charge controller below 2%. The circuit current is the Imp of the PV module: 4.44 A. The circuit operating voltage is the Vmp of the PV module: 18 V.
Voltage drop | = 2 x Circuit current x One-way circuit length (m) x #Wire resistance values|Resistance (Ω/Km) ÷ 1000 |
---|---|
= 2 × 4.44 A × 6m × 6.73 Ω ÷ 1000 = .36 V |
Percentage voltage drop | = Voltage drop ÷ Circuit operating voltage x 100 |
---|---|
= .36 V ÷ 18 V × 100 = 2% |
A 2% voltage drop for this circuit is okay. The wire size is okay.
Phase 5: Terminal temperature ratings
The PV wire is rated at 90°C, but the terminals on the charge controller and breaker are rated at 75°C. It must be verified that the OCPD will still protect these terminals at their lower temperature rating. If the wire is not protected by the OCPD at the temperature rating of the terminals in the circuit, then the wire size must be increased until the circuit passes this test. No other calculations need to be performed again. Increasing the wire size will have the added benefit of decreasing voltage drop.
Step 1: Maximum ampacity based upon terminal temperature rating
Maximum ampacity based upon terminal temperature rating | = Wire size (Phase 2) ampacity at terminal temperature rating from allowable wire ampacity table × Total wire correction parameter (Phase 2) |
---|---|
= 25 A × .8 = 20 A |
Step 2: Verify OCPD protection of terminals
Verify OCPD protection of terminals | = Maximum current considering terminal temperature rating (Step 1) must be greater than the current rating of the chosen OCPD (Phase 3) |
---|---|
= 20 A is greater than the the 10 A current rating of the breaker |
Wire and OCPD size are okay.
Notes/references
- ↑ Trojan Battery Company - Battery Sizing Guidelines https://www.trojanbattery.com/pdf/TRJN0168_BattSizeGuideFL.pdf