Difference between revisions of "Power flow between components"

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A stand-alone PV system behaves differently depending upon environmental conditions and the demands of system users. The [[PV module|PV source]] can generate a limited amount of energy based upon its size and the environmental conditions. The [[Special:MyLanguage/Energy storage|energy storage system]] can only store excess energy that is not consumed by users/loads, but also has a limited storage capacity based upon its size. The [[Special:MyLanguage/Charge controller|charge controller]] serves as an intermediary that helps to regulate flows from the PV source to the energy storage system and loads ([[Special:MyLanguage/Lighting|lighting]], [[Special:MyLanguage/Energy efficient loads|appliances]]. The PV source and the energy storage system will therefore interact in different ways in order to meet the varying power needs of system users. These diagrams do not account for efficiency losses in the system.
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A stand-alone PV system behaves differently depending upon environmental conditions and the demands of system users. The [[Special:MyLanguage/PV module|PV source]] can generate a limited amount of energy based upon its size and the environmental conditions. The [[Special:MyLanguage/Energy storage|energy storage system]] can only store excess energy that is not consumed by the users or loads, but also has a limited storage capacity based upon its size. The [[Special:MyLanguage/Charge controller|charge controller]] serves as an intermediary that helps to regulate flows from the PV source to the energy storage system and loads ([[Special:MyLanguage/Lighting|lighting]], [[Special:MyLanguage/Energy efficient loads|appliances]]). The PV source and the energy storage system will therefore interact in different ways in order to meet the varying power needs of system users. These diagrams do not account for efficiency losses in the system.
  
==Power from PV source flowing to energy storage and loads==
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==Power from PV source flowing to energy storage and loads== <!--T:2-->
  
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If the PV system is generating power, it will first be used to supply any loads that are on. Any excess energy can be stored in the energy storage system.
 
If the PV system is generating power, it will first be used to supply any loads that are on. Any excess energy can be stored in the energy storage system.
 
[[File:Loadscharging-PVdivided2011108.png|frame|center|PV source generates 100 W. 60 W is sent to inverter and loads. 40W is used to charge the energy storage system.]]
 
[[File:Loadscharging-PVdivided2011108.png|frame|center|PV source generates 100 W. 60 W is sent to inverter and loads. 40W is used to charge the energy storage system.]]
  
==PV source is generating excess power==
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==PV source is generating excess power== <!--T:4-->
  
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If the PV source is capable of generating power that cannot be used to supply loads or be stored in the energy storage system, then the charge controller will limit the amount of power that it can supply.
 
If the PV source is capable of generating power that cannot be used to supply loads or be stored in the energy storage system, then the charge controller will limit the amount of power that it can supply.
  
[[File:ExcessPV201108.png|frame|left|PV source can generate 200 W. The inverter/loads are consuming 60W and the energy storage system can only accept 5 W. The charge controller will limit current flow from the PV source in this case.]]
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[[File:ExcessPV201108.png|frame|center|PV source can generate 200 W. The inverter and loads are consuming 60W and the energy storage system can only accept 5 W. The charge controller will limit current flow from the PV source in this case.]]
  
==PV source is generating insufficient power==
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==PV source is generating insufficient power== <!--T:7-->
  
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If the PV source is incapable of generating sufficient power to supply the loads, then the energy storage system will have to supply the excess power. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.
 
If the PV source is incapable of generating sufficient power to supply the loads, then the energy storage system will have to supply the excess power. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.
  
[[File:Excessloads-PV201108.png|frame|left|PV source is generating 100 W. The inverter/loads are consuming 250 W. The energy storage system must supply 150 W to make up the difference.]]
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[[File:Excessloads-PV201108.png|frame|center|PV source is generating 100 W. The inverter and loads are consuming 250 W. The energy storage system must supply 150 W to make up the difference.]]
  
==PV source is not generating power==
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==PV source is not generating power for the loads== <!--T:10-->
  
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If the PV source is generating no energy because the sun has set, then the energy storage system will have to meet all power demand. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.
 
If the PV source is generating no energy because the sun has set, then the energy storage system will have to meet all power demand. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.
  
[[File:Loads-noPV201108.png|frame|left|PV source is not generating any power. The inverter/loads are consuming 250 W. The energy storage system must supply 250 W to meet demand.]]
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[[File:Loads-noPV201108.png|frame|center|PV source is not generating any power. The inverter/loads are consuming 250 W. The energy storage system must supply 250 W to meet demand.]]
  
 
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Latest revision as of 14:06, 8 February 2021

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A stand-alone PV system behaves differently depending upon environmental conditions and the demands of system users. The PV source can generate a limited amount of energy based upon its size and the environmental conditions. The energy storage system can only store excess energy that is not consumed by the users or loads, but also has a limited storage capacity based upon its size. The charge controller serves as an intermediary that helps to regulate flows from the PV source to the energy storage system and loads (lighting, appliances). The PV source and the energy storage system will therefore interact in different ways in order to meet the varying power needs of system users. These diagrams do not account for efficiency losses in the system.

Power from PV source flowing to energy storage and loads

If the PV system is generating power, it will first be used to supply any loads that are on. Any excess energy can be stored in the energy storage system.

PV source generates 100 W. 60 W is sent to inverter and loads. 40W is used to charge the energy storage system.

PV source is generating excess power

If the PV source is capable of generating power that cannot be used to supply loads or be stored in the energy storage system, then the charge controller will limit the amount of power that it can supply.

PV source can generate 200 W. The inverter and loads are consuming 60W and the energy storage system can only accept 5 W. The charge controller will limit current flow from the PV source in this case.

PV source is generating insufficient power

If the PV source is incapable of generating sufficient power to supply the loads, then the energy storage system will have to supply the excess power. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.

PV source is generating 100 W. The inverter and loads are consuming 250 W. The energy storage system must supply 150 W to make up the difference.

PV source is not generating power for the loads

If the PV source is generating no energy because the sun has set, then the energy storage system will have to meet all power demand. If the energy storage system does not have sufficient energy stored, then the voltage will drop and the system will stop functioning.

PV source is not generating any power. The inverter/loads are consuming 250 W. The energy storage system must supply 250 W to meet demand.