Applications: Batteries - PowerPoint PPT Presentation

1 / 14
About This Presentation
Title:

Applications: Batteries

Description:

Thus, the zinc oxidizes instead of the iron. 17-47 ... Allowing a more active metal to oxidize in order to preserve a less active metal. ... – PowerPoint PPT presentation

Number of Views:34
Avg rating:3.0/5.0
Slides: 15
Provided by: Conrad82
Category:

less

Transcript and Presenter's Notes

Title: Applications: Batteries


1
Applications Batteries Corrosion
  • Battery a group of galvanic cells connected in
    series ( to ).
  • Total potential ?E of the battery sum of the
    individual cell potentials.
  • In common usage, a single galvanic cell is often
    referred to as a battery.
  • Sources of direct current, important because of
    portability.

2
  • Primary Battery can not be recharged
  • Secondary Battery rechargeable (storage
    batteries)
  • Fuel Cell reactants supplied from an external
    source

3
  • Lead-Acid Storage Battery (a secondary battery)
  • Provides current for starter motor in cars
  • Anode Pb(s) HSO4(aq) ? PbSO4(s) H(aq) 2
    e
  • E 0.356 V
  • Cathode PbO2(s) HSO4(aq) 3 H(aq) 2 e
    ?
  • PbSO4(s) 2 H2O(l)
  • E 1.685 V
  • Overall Pb(s) PbO2(s) 2 H(aq) 2
    HSO4(aq) ?
  • 2 PbSO4(s) 2 H2O(l)
  • ?E 2.041 V

4
Figure 17.13One of the Six Cells in Storage
Battery a 12-V Lead Storage Battery
5
Some Primary Batteries
  • The Zinc-Carbon (LeClanche) Dry Cell 1866
  • Zn outer shell, C rod in center, paste of NH4Cl,
    ZnCl2, and MnO2 ?E 1.5 V
  • Anode Zn(s) ? Zn2(aq) 2 e
  • Cathode 2 NH4(aq) 2 e ? 2 NH3(g)
    H2(g)
  • Also 2 MnO2(s) H2(g) ? Mn2O3(s) H2O(l)
  • Zn2(aq) 2 NH3(aq) 2 Cl(aq) ?
    Zn(NH3)2Cl2(s)
  • Net 2 MnO2 2 NH4Cl Zn? Mn2O3 H2O
    Zn(NH3)2Cl2

6
Figure 17.14A Common Dry Cell Battery
7
Figure 17.15A Mercury Battery
8
  • The Mercury Button Battery 1.35 V
  • Anode Zn(s) 2 OH(aq) ? ZnO(s) H2O(l) 2 e
  • CathodeHgO(s) H2O(l) 2e? Hg(l) 2 OH(aq)
  • Net Zn(s) HgO(s) ? ZnO(s) Hg(l)

9
Fuel Cells Reactants Continuously Supplied
  • Ex. The H2/O2 Fuel Cell
  • Anode 2 H2(g) 4 OH(aq) ? 4 H2O(l) 4 e
  • Cathode 4 e O2(g) 2 H2O(l) ? 4 OH(aq)
  • Overall 2 H2(g) O2(g) ? 2 H2O(l)

10
Figure 17.16Schematic of the Hydrogen-Oxygen
Fuel Cell
11
Corrosion Unwanted Oxidation
  • Ex rusting of iron
  • Fe2(aq) 2 e ? Fe(s) E 0.44 V
  • Figure 17.17 The Electrochemical Corrosion of
    Iron

12
  • Protection of steel (iron) by galvanizing
    (plating with a layer of zinc)
  • Zn2(aq) 2 e ? Zn(s) E 0.76 V
  • Since this is a lower potential, iron in contact
    with zinc is forced to be cathodic.
  • Net Reaction Zn(s) Fe2(aq) ? Zn2(aq)
    Fe(s)
  • ?E 0.44 (0.76) 0.32 V
  • Thus, the zinc oxidizes instead of the iron.

13
  • Sacrificial Anode Allowing a more active metal
    to oxidize in order to preserve a less active
    metal.
  • Ex Magnesium blocks may be attached to an
    underground iron pipe in order to keep it from
    rusting away.
  • Mg Fe2 ? Mg2 Fe
  • ?E 0.44 (2.37) 1.93 V
  • Mg sacrificial anodes are also found inside home
    water heaters.

14
Figure 17.18Cathodic Protection
Write a Comment
User Comments (0)
About PowerShow.com