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electrical:solar:pwm_tweaking [2017/12/12 09:24] frater_secessus [the controller's achilles heel] |
electrical:solar:pwm_tweaking [2018/04/18 16:52] frater_secessus [the controller's achilles heel] |
====== Tweaking a PWM controller for maximum power ====== | ====== Tweaking a PWM controller for maximum power ====== |
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[[electrical:solar:charge_controller#pwm|PWM controllers]] are inexpensive and durable. Their chief downside is they cannot generate as much power from a given panel as the more expensive [[electrical:solar:charge_controller#mppt|MPPT]] can. This page is intended to help people get the most out of their PWM system. It assumes the 'dweller owns [[electrical:solar:pwm configurable|a configurable PWM controller]]. | [[electrical:solar:charge_controller#pwm|PWM controllers]] are inexpensive and durable. Their chief downside is their ability to generate power is limited when battery voltage is low ([[electrical:solar:charge_controller#mppt|MPPT]] output is unaffected by battery voltage). This page is intended to help people get the most out of their PWM system. It assumes the 'dweller owns [[electrical:solar:pwm configurable|a configurable PWM controller]]. |
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Note: much of this information also applies to [[electrical:solar:shunt_tweaking|tweaking shunt controllers]]. | Note: much of this information also applies to [[electrical:solar:shunt_tweaking|tweaking shunt controllers]]. |
During charging with a PWM controller **the solar panel will be running at the voltage of the battery bank**. Unfortunately, this is almost never the voltage at which the panel makes its rated power (Vmp). The panel will make less and less power when battery voltage is low. | During charging with a PWM controller **the solar panel will be running at the voltage of the battery bank**. Unfortunately, this is almost never the voltage at which the panel makes its rated power (Vmp). The panel will make less and less power when battery voltage is low. |
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This affects charging in all three [[electrical:12v:charging|charging stages]] but it is devastating in [[electrical:12v:charging#bulk_stage|Bulk]]. Let's do some math to see why. | This affects charging in all three [[electrical:12v:charging|charging stages]] but it is devastating in [[electrical:12v:charging#bulk_stage|Bulk]]. Let's do some math to see why.((temperature derating is not considered)) |
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{{ http://bestsolarpanelforhome.com/wp-content/uploads/2017/03/57-79-600x600.jpg?200}}Consider the spec sheet for a random 100w panel (right). 100W is made when the panel is run at 17.8v (Vmp). The current will be around 5.6A (Imp) when the panel is in the usual operating range. | {{ http://bestsolarpanelforhome.com/wp-content/uploads/2017/03/57-79-600x600.jpg?200}}Consider the spec sheet for a random 100w panel (right). 100W is made when the panel is run at 17.8v (Vmp). The current will be around 5.6A (Imp) when the panel is in the usual operating range. |
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17.8v x 5.6A = 99.68w <-- full power, if we could run the panel there. Which we can't with PWM. \\ | 17.8v x 5.6A = 99.68w <-- rating under laboratory conditions \\ |
| 17.8v x 5.6A = 94.70w <-- MPPT running at 95% efficiency \\ |
14.8v x 5.6A = 82.88w <-- power at a high Absorption voltage, as with flooded lead acid \\ | 14.8v x 5.6A = 82.88w <-- power at a high Absorption voltage, as with flooded lead acid \\ |
14.4v x 5.6A = 80.64w <-- power at a lower Absorption voltage \\ | 14.4v x 5.6A = 80.64w <-- power at a lower Absorption voltage \\ |
12.1v x 5.6A = 67.76W <-- power at 50% state of charge; bulk charging | 12.1v x 5.6A = 67.76W <-- power at 50% state of charge; bulk charging |
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This last number shows how far off PWM output can fall when battery voltage is at its lowest.((The last number is also the source of the "30% boost!!!" claims some MPPT makers make. Yes, at that point MPPT at 94.69w (after 5% MPPT efficiency penalty) is 40.2% more than PWM's 67.76w but that is when the disparity is the widest. Most of the time the MPPT charging advantage is lower, perhaps 15%.)) It's also when the battery needs the most current to get out of that deep cycle trough. | This last number shows how far off PWM output can fall when battery voltage (Vbatt) is at its lowest.((The last number is also the source of the "30% boost!!!" claims some MPPT makers make. Yes, at that point MPPT at 94.69w (after 5% MPPT efficiency penalty) is 40.2% more than PWM's 67.76w but that is when the disparity is the widest. Most of the time the MPPT charging advantage is lower, perhaps 15%.)) It's also when the battery needs the most current to get out of that deep cycle trough. |
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===== the plan ===== | ===== the plan ===== |
During the bulk charging stage the battery needs every bit of power it can get. Any loads applied during this stage slow down charging and, more importantly, prevent the system from reaching power-making voltages as soon as possible. | During the bulk charging stage the battery needs every bit of power it can get. Any loads applied during this stage slow down charging and, more importantly, prevent the system from reaching power-making voltages as soon as possible. |
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Wait until your bank is well into Absoroption before using [[electrical:solar:nonessential|discretionary loads]]. | Wait until your bank is well into Absorption before using [[electrical:solar:nonessential|discretionary loads]]. |
==== set Vabs and Vfloat relatively high ==== | ==== set Vabs and Vfloat relatively high ==== |
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