Energizer PP355 user manual

User manual for the device Energizer PP355

Device: Energizer PP355
Category: Battery Charger
Manufacturer: Energizer
Size: 0.62 MB
Added : 5/4/2013
Number of pages: 17
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Summaries

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Abstracts of contents
Summary of the content on the page No. 1

 
Energizer 
Zinc Air Prismatic 
Handbook 
 
Including performance and design data for the PP355  

Summary of the content on the page No. 2

Page  | 2    Energizer Zinc Air Prismatic Handbook    1. Battery Overview ............................................................................................................................. 3  1.1 Zinc Air Chemistry ............................................................................................................................... 3   1.2 Construction .............................................................................................................................

Summary of the content on the page No. 3

Page  | 3    Section 1: Battery Overview      For over 35 years, Energizer has manufactured miniature Zinc Air batteries primarily designed to provide  power to miniature hearing aids.  Zinc Air chemistry provides the highest available energy density  compared to other commercially available batteries.  Energizer Zinc Air Prismatic batteries employ  technology similar to what is used in hearing aid batteries, but with a thin prismatic  form factor  providing power for a broad range of applicatio

Summary of the content on the page No. 4

Page  | 4    Figure 1:  Cross Section View of Zinc Air Prismatic Battery                  Energizer Zinc Air Prismatic batteries are designed to allow air to enter the air holes and to prevent the  transport of liquid electrolyte out of the battery.    A gasket is used to seal between the anode cup and  the cathode can.  The gasket also electrically insulates the negative cup from the positive can.  An air  electrode and a loose layer of Teflon are compressed onto a band of sealant on the bottom

Summary of the content on the page No. 5

Page  | 5    Figure 2:  Runtime for Equivalent Volume AAAA Batteries in 50 mW Devices    50 38 40 30 14 12 20 10 0 AAAA Alkaline Lithium Ion ZAP PP355   The high energy density of Zinc Air is made possible by using a thin air electrode where the cathode  reaction takes place and by using atmospheric oxygen as the cathode reactant.  The result is greater  internal volume for zinc, the active anode material.  More zinc translates into longer runtime in similar  overall  volume.   Figure  3  demons

Summary of the content on the page No. 6

Page  | 6      Figure 4:  Comparison of Discharge Curves at 50 mW Continuous    1.6 1.4 1.2 1.0 0.8 NiMH Zinc Air  AAA PP355 Alkaline  Alkaline  Lithium AAA AAAA AAA 0.6 0.4 0 5 10 15 20 25 30 35 40 45 Discharge Time (hrs)     The impedance of Energizer Zinc Air Prismatic batteries is higher than similar volume Alkaline batteries,  and it decreases slightly through the life of the battery.  The impedance should not impact battery  performance at low to moderate discharge rates.  At higher rate d

Summary of the content on the page No. 7

Page  | 7    Section 2:   PP355 Performance Characteristics      This section describes the performance of the PP355 battery.  Standard discharge curves, performance  at a variety of environmental conditions, pulse capability, and service maintenance data are presented.      2.1 ‐‐ Performance at Standard Conditions    Standard conditions for Energizer Zinc Air Prismatic batteries are defined as 21°C and 50% relative  humidity (RH).  Under these conditions, the PP355 battery is designed to provi

Summary of the content on the page No. 8

Page  | 8    Figure 7:  Comparison of Performance under Continuous Constant Power    Continuous Discharge Time (hrs) AAAA PP355 25 mW 24 88 50 mW 11 38 75 mW 6 24 100 mW 4 15       2.2 ‐‐ Performance at Other Environmental Conditions    When a Zinc Air battery is exposed to a non‐standard environment, a driving force for water transport in  or out of the battery exists.  Movement of water vapor into the battery can fill void space in the anode  cavity under high humidity environments, and moveme

Summary of the content on the page No. 9

Page  | 9    Lower Temperature Conditions:  Air holds less moisture as temperature decreases, and the difference between low and high relative  humidity becomes less significant.  At 0°C, the difference between the humidity of the PP355 and the  environment  is  negligible.   While  the  service  obtained  from  a  PP355  at  temperatures  lower  than  standard conditions is less, the loss is similar to Alkaline batteries.  In general the “up to 3X” service  advantage for Zinc Air batteries over

Summary of the content on the page No. 10

Page  | 10    Figure 8:  Pulse Capability of PP355 Batteries  1 1.1V Cutoff 1.0V Cutoff 0.1 0.9V Cutoff 0.8V Cutoff 0.01 0.001 0.0001 0 200 400 600 800 1000 1200 1400 1600 Current (mA)   2.4 ‐‐ Service Maintenance    Zinc Air batteries are stored with adhesive backed tabs prior to use.  These tabs seal the air holes against  oxygen and water ingress.  To obtain the full battery performance, the tab should be removed only  immediately prior to use.  When the battery is sealed by the tab, service 

Summary of the content on the page No. 11

Page  | 11    2.5 ‐‐ Activation Time and Air Requirements    When batteries are stored with the adhesive tab intact, they have a lower open circuit voltage (OCV)  since the oxygen contained in the battery is consumed during storage.  When the tab is removed the  OCV will rise as oxygen activates the air electrode.  With multiple air holes for added rate capability, the  PP355 may take a couple of seconds to air up enough to sustain a 50 mW load above 1 volt.  Based on  the time it will take a co

Summary of the content on the page No. 12

Page  | 12    Section 3:   Application and Design Considerations      Excessive exposure to air can have an adverse affect on Zinc Air battery operation, primarily due to  carbon dioxide reacting with the electrolyte in the air electrode.  The battery can also absorb water or  dry out depending on ambient conditions.  Balancing the air requirement of the battery during discharge  versus the need to minimize exposure during rest is called air management.  Air management might be  as simple as rem

Summary of the content on the page No. 13

Page  | 13    Figure 11:  Overview of Different Air Management Techniques   high  high degree of air management needed,  none or small  cell has high air access but is expected to  degree of air  be in service with long periods of “off”  management  time (>3 months) needed, since cell  capacity is quickly  used (1‐3 months) throttling needed to  maximize service  time  (>3 months) low  continuous intermittent Duty Cycle     3.2 ‐‐ Elements of Air Management    Two elements of a successful in‐dev

Summary of the content on the page No. 14

Page  | 14    Figure 12:  Air Management Design Concept            3.3 ‐‐ Battery Compartment    The design of a Zinc Air Prismatic battery compartment depends on several factors including battery  dimensions,  battery  orientation,  and  air  flow  needed  to  maintain  power  to  the  device.   Other  considerations are the ease of battery insertion and removal, contact materials, reversal protection, and  the shape and location of device contacts.  In general, consumers should be able to use 

Summary of the content on the page No. 15

Page  | 15    Contact Materials:  Nickel plated stainless steel is recommended because it provides good conductivity and environmental  stability at a reasonable cost.  Nickel plating must be adherent, continuous, and non‐porous.  The nickel  plating must also resist the wear that occurs during the insertion and extraction of batteries.  The  suggested plating thickness is 5‐6 micrometers.     Battery Orientation:  How the battery is situated in the compartment is an important design considerati

Summary of the content on the page No. 16

Page  | 16    3.4 ‐‐ Multi‐Battery Applications    In  some  situations,  a  higher  voltage  or  an  increased  performance  level  is  desired  for  a  certain  application.  Zinc Air batteries can be arranged in series or in parallel as needed.  Devices that use more  than one Zinc Air Prismatic battery introduce additional design considerations.  An air plenum and air  access is required for each battery, and these can be independent or shared.  Additionally, stacked  batteries require space

Summary of the content on the page No. 17

Page  | 17    Section 4: Handling Procedures      4.1 ‐‐ Recommended Operating and Storage Conditions    For optimum performance and capacity retention, Zinc Air Prismatic batteries should be used in a  temperature range of ‐10⁰C to 55⁰C and in a relative humidity range of 25% to 80%.  Zinc Air batteries  should be stored between 10°C and 30°C and at 40% to 70% relative humidity.  Batteries should be  stored with the tab in place to prevent performance degradation due to environmental exposure. 


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