Memory effect: Difference between revisions
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{{Short description|Capacity loss in rechargeable batteries}} |
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'''Memory effect''', also known as '''battery effect''', '''lazy battery effect''', or '''battery memory''', is an effect observed in [[nickel-cadmium]] |
'''Memory effect''', also known as '''battery effect''', '''lazy battery effect''', or '''battery memory''', is an effect observed in [[nickel-cadmium]] [[rechargeable battery|rechargeable batteries]] that causes them to hold less charge.<ref name="BergveldKruijt2002">{{cite book|last1=Bergveld|first1=H.J.|last2=Kruijt|first2=W.S.|last3=Notten|first3=Peter H. L.|title=Battery Management Systems: Design by Modelling|url=https://books.google.com/books?id=FVvo7W3Y7wgC&pg=PA38|access-date=5 June 2013|date=2002-09-30|publisher=Springer|isbn=9781402008320|pages=38–}}</ref><ref name="Duracell">{{cite web |
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|url=http://www.duracell.com/oem/rechargeable/Nickel/voltdep.asp |
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|archive-url=https://web.archive.org/web/20090303131745/http://www.duracell.com/oem/rechargeable/Nickel/voltdep.asp |
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|archive-date=March 3, 2009 |
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|title=Voltage Depression ("Memory Effect") |
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|website=Duracell.com |
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|publisher=[[Procter & Gamble]] |
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|access-date=September 15, 2015}}</ref> It describes the situation in which nickel-cadmium batteries gradually lose their maximum energy capacity if they are repeatedly recharged after being only partially discharged. The battery appears to "remember" the smaller capacity.<ref>{{Cite book|first1=David|last1=Linden|first2=Thomas B.|last2=Reddy|title=Handbook Of Batteries|edition=3rd|publisher=McGraw-Hill|location=New York|date=2002|isbn=0-07-135978-8|page=[https://archive.org/details/handbookofbatter0000unse/page/28 28-18]|url-access=registration|url=https://archive.org/details/handbookofbatter0000unse/page/28}}</ref> |
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==True memory effect== |
==True memory effect== |
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The term "memory" came from an aerospace nickel-cadmium application in which the cells were repeatedly discharged to 25% of available capacity ( |
The term "memory" came from an aerospace nickel-cadmium application in which the cells were repeatedly discharged to 25% of available capacity (give or take 1%) by exacting computer control, then recharged to 100% capacity without overcharge.<ref name=GEnote /> This long-term, repetitive [[Charge cycle|cycle]] régime, with no provision for overcharge, resulted in a loss of capacity beyond the 25% discharge point. True memory cannot exist if any one (or more) of the following conditions holds: |
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* batteries achieve full overcharge. |
* batteries achieve full overcharge. |
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* discharge is not exactly the same each cycle, within plus or minus 3% |
* discharge is not exactly the same each cycle, within plus or minus 3% |
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* discharge is to less than 1.0 volt per cell<ref name=GEnote>[http://www.repairfaq.org/ELE/F_Battery_info.html Repair FAQ, quoting GE tech note] Davolio, G., & Soragni, E. (1998). Journal of Applied Electrochemistry, 28(12), 1313–1319. doi:10.1023/a:1003452327919 |
* discharge is to less than 1.0 volt per cell<ref name=GEnote>[http://www.repairfaq.org/ELE/F_Battery_info.html Repair FAQ, quoting GE tech note] Davolio, G., & Soragni, E. (1998). Journal of Applied Electrochemistry, 28(12), 1313–1319. doi:10.1023/a:1003452327919</ref> |
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True memory-effect is specific to [[sintering|sintered-plate]] nickel-cadmium cells, and is exceedingly difficult to reproduce, especially in lower ampere-hour cells. In one particular test program designed to induce the effect, none was found after more than 700 precisely-controlled charge/discharge cycles. In the program, spirally-wound one-ampere-hour cells were used. In a follow-up program, 20-ampere-hour aerospace-type cells were used on a similar test régime; memory effects were observed after a few hundred cycles.<ref> |
True memory-effect is specific to [[sintering|sintered-plate]] nickel-cadmium cells, and is exceedingly difficult to reproduce, especially in lower ampere-hour cells. In one particular test program designed to induce the effect, none was found after more than 700 precisely-controlled charge/discharge cycles. In the program, spirally-wound one-ampere-hour cells were used. In a follow-up program, 20-ampere-hour aerospace-type cells were used on a similar test régime; memory effects were observed after a few hundred cycles.<ref>{{Cite web|url=http://www.repairfaq.org/ELE/F_Battery_info.html|title=Sci.Electronics FAQ: More Battery Info|website=www.repairfaq.org}}</ref> |
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[http://www.repairfaq.org/ELE/F_Battery_info.html Repair FAQ, quoted above, but not directly quoting GE tech note] |
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</ref> |
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==Other problems perceived as memory effect== |
==Other problems perceived as memory effect== |
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Phenomena which are not true memory effects may also occur in battery types other than sintered-plate nickel-cadmium cells. In particular lithium-based cells, not normally subject to the memory effect, may change their voltage levels so that a virtual decrease of capacity may be perceived by the battery control system.<ref>{{cite web|title=Memory effect now also found in lithium-ion batteries|url=https://phys.org/news/2013-04-memory-effect-lithium-ion-batteries.html|publisher=Paul Scherrer Institute| |
Phenomena which are not true memory effects may also occur in battery types other than sintered-plate nickel-cadmium cells. In particular, lithium-based cells, not normally subject to the memory effect, may change their voltage levels so that a virtual decrease of capacity may be perceived by the battery control system.<ref>{{cite web|title=Memory effect now also found in lithium-ion batteries|url=https://phys.org/news/2013-04-memory-effect-lithium-ion-batteries.html|publisher=Paul Scherrer Institute|access-date=10 April 2021}}</ref> |
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===Temporary effects=== |
===Temporary effects=== |
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A common process often ascribed to memory effect is voltage depression. In this case, the output voltage of the battery drops more quickly than normal as it is used, even though the total capacity remains almost the same. In modern electronic equipment that monitors the voltage to indicate battery charge, the battery appears to be draining very quickly. To the user, it appears the battery is not holding its full charge, which seems similar to memory effect. This is a common problem with high-load devices such as [[digital camera]]s and cell phones. |
A common process often ascribed to memory effect is voltage depression. In this case, the output voltage of the battery drops more quickly than normal as it is used, even though the total capacity remains almost the same. In modern electronic equipment that monitors the voltage to indicate battery charge, the battery appears to be draining very quickly. To the user, it appears the battery is not holding its full charge, which seems similar to memory effect. This is a common problem with high-load devices such as [[digital camera]]s and cell phones. |
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Voltage depression is caused by repeated over-charging of a battery, which causes the formation of small crystals of [[electrolyte]] on the plates. These can clog the plates, increasing resistance and lowering the voltage of some individual cells in the battery. This causes the battery as a whole to seem to discharge rapidly as those individual cells discharge quickly and the voltage of the battery as a whole suddenly falls. This effect is very common, as consumer [[Trickle charging|trickle chargers]] typically overcharge. |
Voltage depression is caused by repeated over-charging of a battery, which causes the formation of small crystals of [[electrolyte]] on the plates. {{Citation needed|date=August 2023}} These can clog the plates, increasing resistance and lowering the voltage of some individual cells in the battery. This causes the battery as a whole to seem to discharge rapidly as those individual cells discharge quickly and the voltage of the battery as a whole suddenly falls. {{Citation needed|date=August 2023}} This effect is very common, {{Citation needed|date=August 2023}} as consumer [[Trickle charging|trickle chargers]] typically overcharge. [[Nickel–metal hydride]] batteries, for example, are known to experience this form of capacity loss {{Citation needed|date=August 2023}} often mistakenly attributed to memory effect.<ref name="Duracell"/> |
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=====Repair===== |
=====Repair===== |
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The effect can be overcome by subjecting each cell of the battery to one or more deep charge/discharge cycles.<ref> |
The effect can be overcome by subjecting each cell of the battery to one or more deep charge/discharge cycles.<ref>{{Cite web|url=http://www2.eng.cam.ac.uk/~dmh/ptialcd/battery/index.htm|title=Batteries as sources of electrical power|website=www2.eng.cam.ac.uk}}</ref> This must be done to the individual cells, not a multi-cell battery; in a battery, some cells may discharge before others, resulting in those cells being subjected to a reverse charging current by the remaining cells, potentially leading to irreversible damage. |
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====High temperatures==== |
====High temperatures==== |
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====Other causes==== |
====Other causes==== |
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* Operation below 32 |
* Operation below 32 °F (0 °C) |
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* High discharge rates (above 5C) in a battery not specifically designed for such use |
* High discharge rates (above 5C) in a battery not specifically designed for such use |
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* Inadequate charging time |
* Inadequate charging time |
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====Age and use—normal end-of-life==== |
====Age and use—normal end-of-life==== |
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All rechargeable batteries have a finite lifespan and will slowly lose storage capacity as they age due to secondary chemical reactions within the battery whether it is used or not. Some cells may fail sooner than others, but the effect is to reduce the voltage of the battery. [[Lithium-ion battery|Lithium-based]] batteries have one of the longest idle lives of any construction. Unfortunately the number of operational cycles is still quite low at approximately 400–1200 complete charge/discharge cycles.<ref>[https://web.archive.org/web/20161107091002/http://www.thermoanalytics.com/products/battery-module/hev-management Battery Types and Characteristics for HEV] ThermoAnalytics, Inc., 2007. Retrieved 2010-06-11.</ref> The lifetime of lithium batteries decreases at higher temperature and [[state of charge|states of charge]] (SoC), whether used or not; maximum life of lithium cells when not in use(storage) is achieved by refrigerating (without freezing) charged to 30%–50% SoC. To prevent overdischarge, battery should be brought back to room temperature and recharged to 50% SoC once every six months or once per year.<ref>{{cite web|title=Lithium-Ion Battery Maintenance ZZZ Guidelines|url=http://www.newark.com/pdfs/techarticles/tektronix/LIBMG.pdf|publisher=Tektronix, Inc.| |
All rechargeable batteries have a finite lifespan and will slowly lose storage capacity as they age due to secondary chemical reactions within the battery whether it is used or not. Some cells may fail sooner than others, but the effect is to reduce the voltage of the battery. [[Lithium-ion battery|Lithium-based]] batteries have one of the longest idle lives of any construction. Unfortunately the number of operational cycles is still quite low at approximately 400–1200 complete charge/discharge cycles.<ref>[https://web.archive.org/web/20161107091002/http://www.thermoanalytics.com/products/battery-module/hev-management Battery Types and Characteristics for HEV] ThermoAnalytics, Inc., 2007. Retrieved 2010-06-11.</ref> The lifetime of lithium batteries decreases at higher temperature and [[state of charge|states of charge]] (SoC), whether used or not; maximum life of lithium cells when not in use(storage) is achieved by refrigerating (without freezing) charged to 30%–50% SoC. To prevent overdischarge, battery should be brought back to room temperature and recharged to 50% SoC once every six months or once per year.<ref>{{cite web|title=Lithium-Ion Battery Maintenance ZZZ Guidelines|url=http://www.newark.com/pdfs/techarticles/tektronix/LIBMG.pdf|publisher=Tektronix, Inc.|access-date=16 December 2013}}</ref><ref>{{cite web|title=Lithium-Ion & Lithium Polymer Cells and Batteries Safety Precautions like|url=http://ultralifecorporation.com/download/168/|publisher=Ultralife corporation|access-date=16 December 2013}}</ref> |
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==References== |
==References== |
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{{ |
{{reflist}} |
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==Further reading== |
==Further reading== |
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* ''Rechargeable Batteries Applications Handbook'' from Gates Energy Products, published since 1992 April 10. |
* ''Rechargeable Batteries Applications Handbook'' from Gates Energy Products, published since 1992 April 10. |
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{{DEFAULTSORT:Memory Effect}} |
{{DEFAULTSORT:Memory Effect}} |
Latest revision as of 00:51, 17 September 2023
This article needs additional citations for verification. (January 2007) |
Memory effect, also known as battery effect, lazy battery effect, or battery memory, is an effect observed in nickel-cadmium rechargeable batteries that causes them to hold less charge.[1][2] It describes the situation in which nickel-cadmium batteries gradually lose their maximum energy capacity if they are repeatedly recharged after being only partially discharged. The battery appears to "remember" the smaller capacity.[3]
True memory effect
[edit]The term "memory" came from an aerospace nickel-cadmium application in which the cells were repeatedly discharged to 25% of available capacity (give or take 1%) by exacting computer control, then recharged to 100% capacity without overcharge.[4] This long-term, repetitive cycle régime, with no provision for overcharge, resulted in a loss of capacity beyond the 25% discharge point. True memory cannot exist if any one (or more) of the following conditions holds:
- batteries achieve full overcharge.
- discharge is not exactly the same each cycle, within plus or minus 3%
- discharge is to less than 1.0 volt per cell[4]
True memory-effect is specific to sintered-plate nickel-cadmium cells, and is exceedingly difficult to reproduce, especially in lower ampere-hour cells. In one particular test program designed to induce the effect, none was found after more than 700 precisely-controlled charge/discharge cycles. In the program, spirally-wound one-ampere-hour cells were used. In a follow-up program, 20-ampere-hour aerospace-type cells were used on a similar test régime; memory effects were observed after a few hundred cycles.[5]
Other problems perceived as memory effect
[edit]Phenomena which are not true memory effects may also occur in battery types other than sintered-plate nickel-cadmium cells. In particular, lithium-based cells, not normally subject to the memory effect, may change their voltage levels so that a virtual decrease of capacity may be perceived by the battery control system.[6]
Temporary effects
[edit]Voltage depression due to long-term over-charging
[edit]A common process often ascribed to memory effect is voltage depression. In this case, the output voltage of the battery drops more quickly than normal as it is used, even though the total capacity remains almost the same. In modern electronic equipment that monitors the voltage to indicate battery charge, the battery appears to be draining very quickly. To the user, it appears the battery is not holding its full charge, which seems similar to memory effect. This is a common problem with high-load devices such as digital cameras and cell phones.
Voltage depression is caused by repeated over-charging of a battery, which causes the formation of small crystals of electrolyte on the plates. [citation needed] These can clog the plates, increasing resistance and lowering the voltage of some individual cells in the battery. This causes the battery as a whole to seem to discharge rapidly as those individual cells discharge quickly and the voltage of the battery as a whole suddenly falls. [citation needed] This effect is very common, [citation needed] as consumer trickle chargers typically overcharge. Nickel–metal hydride batteries, for example, are known to experience this form of capacity loss [citation needed] often mistakenly attributed to memory effect.[2]
Repair
[edit]The effect can be overcome by subjecting each cell of the battery to one or more deep charge/discharge cycles.[7] This must be done to the individual cells, not a multi-cell battery; in a battery, some cells may discharge before others, resulting in those cells being subjected to a reverse charging current by the remaining cells, potentially leading to irreversible damage.
High temperatures
[edit]High temperatures can also reduce the charged voltage and the charge accepted by the cells.[4]
Other causes
[edit]- Operation below 32 °F (0 °C)
- High discharge rates (above 5C) in a battery not specifically designed for such use
- Inadequate charging time
- Defective charger[4]
Permanent loss of capacity
[edit]Deep discharge
[edit]Some rechargeable batteries can be damaged by repeated deep discharge. Batteries are composed of multiple similar, but not identical, cells. Each cell has its own charge capacity. As the battery as a whole is being deeply discharged, the cell with the smallest capacity may reach zero charge and will "reverse charge" as the other cells continue to force current through it. The resulting loss of capacity is often ascribed to the memory effect.
Battery users may attempt to avoid the memory effect proper by fully discharging their battery packs. This practice is likely to cause more damage as one of the cells will be deep discharged. The damage is focused on the weakest cell, so that each additional full discharge will cause more and more damage to that cell.
Age and use—normal end-of-life
[edit]All rechargeable batteries have a finite lifespan and will slowly lose storage capacity as they age due to secondary chemical reactions within the battery whether it is used or not. Some cells may fail sooner than others, but the effect is to reduce the voltage of the battery. Lithium-based batteries have one of the longest idle lives of any construction. Unfortunately the number of operational cycles is still quite low at approximately 400–1200 complete charge/discharge cycles.[8] The lifetime of lithium batteries decreases at higher temperature and states of charge (SoC), whether used or not; maximum life of lithium cells when not in use(storage) is achieved by refrigerating (without freezing) charged to 30%–50% SoC. To prevent overdischarge, battery should be brought back to room temperature and recharged to 50% SoC once every six months or once per year.[9][10]
References
[edit]- ^ Bergveld, H.J.; Kruijt, W.S.; Notten, Peter H. L. (2002-09-30). Battery Management Systems: Design by Modelling. Springer. pp. 38–. ISBN 9781402008320. Retrieved 5 June 2013.
- ^ a b "Voltage Depression ("Memory Effect")". Duracell.com. Procter & Gamble. Archived from the original on March 3, 2009. Retrieved September 15, 2015.
- ^ Linden, David; Reddy, Thomas B. (2002). Handbook Of Batteries (3rd ed.). New York: McGraw-Hill. p. 28-18. ISBN 0-07-135978-8.
- ^ a b c d Repair FAQ, quoting GE tech note Davolio, G., & Soragni, E. (1998). Journal of Applied Electrochemistry, 28(12), 1313–1319. doi:10.1023/a:1003452327919
- ^ "Sci.Electronics FAQ: More Battery Info". www.repairfaq.org.
- ^ "Memory effect now also found in lithium-ion batteries". Paul Scherrer Institute. Retrieved 10 April 2021.
- ^ "Batteries as sources of electrical power". www2.eng.cam.ac.uk.
- ^ Battery Types and Characteristics for HEV ThermoAnalytics, Inc., 2007. Retrieved 2010-06-11.
- ^ "Lithium-Ion Battery Maintenance ZZZ Guidelines" (PDF). Tektronix, Inc. Retrieved 16 December 2013.
- ^ "Lithium-Ion & Lithium Polymer Cells and Batteries Safety Precautions like". Ultralife corporation. Retrieved 16 December 2013.
Further reading
[edit]- Rechargeable Batteries Applications Handbook from Gates Energy Products, published since 1992 April 10.