Difference between revisions of "Energy storage"

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Batteries often contain extremely hazardous materials. It is important to understand the proper precautions that need to be taken when working any battery and to wear personal protection equipment as necessary. This information should be available in the user manual and specifications sheet.
 
Batteries often contain extremely hazardous materials. It is important to understand the proper precautions that need to be taken when working any battery and to wear personal protection equipment as necessary. This information should be available in the user manual and specifications sheet.
  
For electrical safety with batteries visit: [[Electrical safety#Safety with batteries|Electrical safety with batteries]]
+
For electrical safety with batteries - see [[Electrical safety#Safety with batteries|Electrical safety with batteries]]
  
 
===Recycling===
 
===Recycling===

Revision as of 14:01, 27 November 2020

A small hypothetical off-grid system
Yellow is potential PV power on a sunny day. Grey is potential PV power on a partially cloudy day. Blue is potential PV power on a rainy day. Orange represents the hypothetical power needs of a typical system's users. None of the production lines align with power needs of the users.

Renewables, like solar, produce energy when the environmental conditions are favorable. PV systems function when the sun is shining, but their production varies significantly depending on whether it is cloudy or raining. There is also the inevitable reality of the sun setting each day. Variable production requires energy storage to provide a stable energy source and voltage when the the PV source is not producing power to meet the energy demand. The most common form of storage in off-grid applications is batteries. Rechargeable batteries rely on chemical reactions to release energy when it is needed, but that can be run in reverse when the battery is being charged to store energy. There are many different types and sizes of batteries in the market. This is the case because there is no single type of battery that is superior in all applications. Each type of battery has uses different combinations of materials that have different advantages and disadvantages. All battery designs inevitably have to balance the following characteristics:

  • Cycle life (life span)
  • Cost
  • Specific energy (energy capacity relative to size)
  • Specific power (power capacity relative to size)
  • Safety
  • Performance under variable conditions
  • Maintenance

A battery may have a long life span and be able to handle large loads, but it will have large and heavy or cost too much. A battery may be able to supply lots of power and be realtively small in size, but it will not have a long lifespan. A battery must therefore be chosen based upon the particular application. One type of battery will be appropriate for a portable radio and another type will be appropriate for storage in a PV system. Small-scale PV systems with batteries typically rely upon lead acid batteries as they are a good compromise between all of these different factors.

Every type of battery has specific conditions for use that must be must be followed. It is very important to read the user manual and specifications sheet for any time of battery to make sure that it will be appropriate for its intended use. Failure to choose the right battery or failure to use it properly can damage equipment or cause injury.

The energy storage system for an off-grid system must will be sized and selected based upon the load evaluation for a particular site - see Energy storage sizing and selection for more information.

Characteristics of batteries

The three most important characteristics when choosing a battery are:

Voltage

Batteries are rated with a nominal voltage (Vn). This voltage is called a nominal voltage as the voltage of batteries constantly varies depending on if they are being charged/discharged, their state of charge and the cell temperature.

Storage capacity

The energy storage capacity of a battery will be rated in amp-hours (Ah). or watt-hours (Wh). 1 amp-hour is equal to 1 amp of current transferred during the course of an hour, which is the standard rating method used for lead acid batteries. In the PV sector it is becoming more common to rate batteries in Watt-hours because it is easier to understand the total storage capacity of an energy storage system. To be able to compare the storage capacity of a system to the potential loads it is necessary to convert from amp-hours to watt-hours. The formula is simple:

Storage capacity = Ah × Vn

Example 1: There is a 12 V 120 Ah battery. What is the capacity of the battery?
Storage capacity = 12 V × 120 Ah
Storage capacity = 1440 Wh
Example 2: There are two batteries connected together that are each 12 V and 60 Ah. What is the capacity of the battery bank?
Storage capacity = 12 V × 60 Ah × 2 batteries
Storage cpacity = 1440 Wh

Different sizes and voltage of batteries can be conneted together to achieve the same amount of storage capacity.

Cycle life

Cycle life is the number of charge and discharge cycles that an energy storage device can provide before performance decreases to an extent that it cannot perform as required. The cycle life, or longevity, of all batteries depends upon the following factors:

  1. Depth of discharge (DoD)
  2. Temperature
  3. Proper charging
  4. Maintenance

Using batteries

The life of a battery is greatly affecting by how it is charged, discharged, maintained and under what conditions it is used.

State of charge (SoC)

The state of charge (SoC) of a battery is the total amount of its storage capacity that remains available for use. It is important for system users to understand how much energy remains for use to avoid damaging the battery by withdrawing too much energy. For example, if 25% of the capacity of a battery has been used, then its state of charge will be 75%. A fully AGM battery will have a voltage of around 12.8 V and an empty battery will have a voltage of around 10.5 V. If a battery is being discharged, its voltage will drop and if it is being charged its voltage will increase. In a PV system, which is constantly being charged and discharged, this can make it difficult to get a proper state of charge measurement from voltage. Nonetheless, many small-scale battery-based systems do not rely on a shunt and users commonly use the voltage of the battery bank as their only guide. To get an accurate measurement of state of charge there are three options:

State of charge vs. depth of discharge for a Trojan lead acid AGM battery [1].
  1. The ideal method to measure the state of charge of a battery is to use a device called a shunt. A shunt is a device that can measure the amount of current flowing in and out of battery to estimate its available capacity.
  2. Disconnecting all of the loads and charging sources and then waiting three hours to let the voltage stabilize.
  3. The state of charge of a flooded lead acid battery can be taken using a specialized device called a hydrometer that takes a mesurement of the electrolyte soluton inside the battery. These devices are not available everywhere and if used improperly can be hazardous as the electrolyte solution inside a battery is highly acidic.

Depth of discharge (DoD)

Depth of discharge is the inverse of state of charge - it is the amount of the storage capacity that has been removed. Depth of discharge is important when designing PV systems as it determines the size of the energy storage system and how many cycles it will last for. Lead acid batteries are not tolerant of regular deep discharges - a typical lead acid battery should not be discharged more than 50% regularly as it will greatly shorten its cycle life. Lithium ion batteries are far more tolerance of regular deep cycling. The actual usable energy in battery bank is calculated as follow:

Usable energy = Storage capacity × Depth of discharge

Example 1: You have a battery bank with 1440Wh of capacity, but the system is only designed to be used to a depth of discharge of 40%. How much usable energy is there?
Usable energy = 1440 Wh × .4
Usable energy = 576 Wh

Proper charging

All battery types have a maximum charging current and maximum charging voltage based upon the battery's temperature. A battery must be paired with a Charge controller that is designed for use with that type of battery. Each individual battery make and model will have its own specific characteristics that will have to be programmed into the charge controller.

Cell temperature

Regardless of the battery type, heat greatly affects performance and shortens the cycle life of a battery. For lead acid batteries it is estimated that for every 10°C increase in average temperature above 25°C shortens the batteries life by half. This means that operating a lead acid battery for one month at 35°C is equivalent in terms of battery life to operating the battery for two months at 25°C[1].

Maintenance

Basic personal protective equipment (PPE) for working with batteries.

Each battery type has specific maintenance requirements and this becomes a major factor when selecting batteries. If a battery bank is not properly maintained it can be quickly destroyed, but maintenance-free batteries typically cost signficantly more and may have shorter life spans.

Safety

Batteries often contain extremely hazardous materials. It is important to understand the proper precautions that need to be taken when working any battery and to wear personal protection equipment as necessary. This information should be available in the user manual and specifications sheet.

For electrical safety with batteries - see Electrical safety with batteries

Recycling

As batteries contain hazardous materials they must be disposed of properly. Batteries can be recycled nearly anywhere in the world and there is often a deposit for their return as they contain valuable materials.

Notes