Presentation is loading. Please wait.

Presentation is loading. Please wait.

More Protection Techniques. Direct Electrical Protection When a metal corrodes it loses electrons (oxidation). If electrons could be ‘pushed’ back onto.

Published bySherman Holmes Modified over 8 years ago

Similar presentations

Presentation on theme: "More Protection Techniques. Direct Electrical Protection When a metal corrodes it loses electrons (oxidation). If electrons could be ‘pushed’ back onto."— Presentation transcript:

1 More Protection Techniques

2 Direct Electrical Protection When a metal corrodes it loses electrons (oxidation). If electrons could be ‘pushed’ back onto the metal then it would not corrode. If the metal is connected to the negative terminal of any direct electrical supply like a battery, a supply of electrons can be provided, and so prevents corrosion. If the metal is connected to the negative terminal of any direct electrical supply like a battery, a supply of electrons can be provided, and so prevents corrosion. This method of protection is most widely used in cars and trucks where the negative terminal of the battery is connected to the steel bodywork. This method of protection is most widely used in cars and trucks where the negative terminal of the battery is connected to the steel bodywork.

3 Sacrificial Protection Water + Ferroxyl indicator

4 Results: Test tubeObservation 1Lots of blue colour 2No blue colour + pink colour present 3Little blue colour Conclusion: Since Mg is higher in the ECS than Fe, it loses electrons and ‘pushes’ them onto iron. Mg (s)  Mg 2+ + 2e - This prevents Fe from corroding, but Mg corrodes  Sacrificial protection.

5 When two metals are joined together in a simple cell, electrons will flow from the metal higher in the electrochemical series to the one lower down in the series.

6 Uses: Magnesium, which is higher than zinc in the electrochemical series will give even better protection as it loses electrons more readily. Magnesium, which is higher than zinc in the electrochemical series will give even better protection as it loses electrons more readily. Underground gas pipes can be protected from corrosion by attaching scraps of magnesium at regular intervals. Underground gas pipes can be protected from corrosion by attaching scraps of magnesium at regular intervals. Some ships have blocks of zinc attached to their hulls to protect them against the corrosive action of seawater. Some ships have blocks of zinc attached to their hulls to protect them against the corrosive action of seawater.

7 Tin-plating is another example of sacrificial protection. Tin-plate is used to make tin cans for food. If a tin can is bashed or scratched, the steel below becomes exposed. Rusting rapidly occurs as the iron quickly loses electrons which flow to the tin. In this way, the iron is ‘sacrificed’ and the tin is protected.

8 * Anodising – Protecting Aluminium * Some metal corrode to form a flaky oxide layer or oxide layer which reacts with other chemicals. Some metal corrode to form a flaky oxide layer or oxide layer which reacts with other chemicals. Aluminium  smooth oxide layer which does not react further. Aluminium  smooth oxide layer which does not react further. Aluminium oxide layer  protects metal and so we deliberately increase this layer. Aluminium oxide layer  protects metal and so we deliberately increase this layer.

9 Oxide layer: 1 Resistant to chemical attack 2 Allows a dye to be applied – improve appearance

Download ppt "More Protection Techniques. Direct Electrical Protection When a metal corrodes it loses electrons (oxidation). If electrons could be ‘pushed’ back onto."

Similar presentations

Topic 7 - Corrosion.

Topic 7 - Corrosion.
Bridge Corrosion A look at the corrosion of steel in Bridges.

Bridge Corrosion A look at the corrosion of steel in Bridges.
Preventing Corrosion. Corrosion can be prevented in a number of ways: Corrosion can be prevented in a number of ways: Physical protection Physical protection.

Preventing Corrosion. Corrosion can be prevented in a number of ways: Corrosion can be prevented in a number of ways: Physical protection Physical protection.
eymmcl2003 12345 6789101112 1314151617 eymmcl2003 1 Why does scratched, tin plated iron rust faster than non-plated iron? answer Electrons flow from.

eymmcl eymmcl Why does scratched, tin plated iron rust faster than non-plated iron? answer Electrons flow from.
Topic 12 Corrosion Aim: Aim: To find out To find out –What is corrosion? –What is required for corrosion to occur?

Topic 12 Corrosion Aim: Aim: To find out To find out –What is corrosion? –What is required for corrosion to occur?
Chapter 13: Properties of Metals

Chapter 13: Properties of Metals
Y12 HSC Chemistry Shipwrecks and Corrosion R. Slider

Y12 HSC Chemistry Shipwrecks and Corrosion R. Slider
Metals Nat 5 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37.

Metals Nat
The Rusting of Iron Aim:

The Rusting of Iron Aim:
Electrolytic Cells Is a Galvanic Cell forced to operate in reverse Process is called electrolysis This occurs if a voltage greater than that produced by.

Electrolytic Cells Is a Galvanic Cell forced to operate in reverse Process is called electrolysis This occurs if a voltage greater than that produced by.
Displacement Reactions By the end of this lesson I should be able to: 1.Use the Electrochemical series to explain why displacement reactions occur and.

Displacement Reactions By the end of this lesson I should be able to: 1.Use the Electrochemical series to explain why displacement reactions occur and.
Do Now! Describe how aluminium can rust, and how it’s different to rusting iron (use the information found in the “Iron and Aluminium” worksheet) Aluminum.

Do Now! Describe how aluminium can rust, and how it’s different to rusting iron (use the information found in the “Iron and Aluminium” worksheet) Aluminum.
Experiment on HOW RUSTING CAN BE PREVENTED BY USING SACRIFICIAL METHOD

Experiment on HOW RUSTING CAN BE PREVENTED BY USING SACRIFICIAL METHOD
OXIDATION- REDUCTION REACTIONS REDOX. Oxygen Reactions Early chemists saw oxidation only as the combination of an element with oxygen to produce an oxide.

OXIDATION- REDUCTION REACTIONS REDOX. Oxygen Reactions Early chemists saw oxidation only as the combination of an element with oxygen to produce an oxide.
Fuel cells differ from batteries in that the former do not store chemical energy. Reactants must be constantly resupplied and products must be constantly.

Fuel cells differ from batteries in that the former do not store chemical energy. Reactants must be constantly resupplied and products must be constantly.
Chapter Nine Electrochemistry Applications. Copyright © Houghton Mifflin Company. All rights reserved.9 | 2 Batteries and Fuel Cells We’ve seen examples.

Chapter Nine Electrochemistry Applications. Copyright © Houghton Mifflin Company. All rights reserved.9 | 2 Batteries and Fuel Cells We’ve seen examples.
Corrosion Prevention Corrosion of steel, which consists mainly of iron, is a major problem in our society. But steps can be taken to prevent it.

Corrosion Prevention Corrosion of steel, which consists mainly of iron, is a major problem in our society. But steps can be taken to prevent it.
Corrosion of metals and their protection

Corrosion of metals and their protection
Intermediate 1 Unit 2a Metals 1 23 4567 89 10 111213 14 15 22 23242526 27 161718192021.

Intermediate 1 Unit 2a Metals
Lesson 2. Galvanic Cells In the reaction between Zn and CuSO 4, the zinc is oxidized by copper (II) ions. Zn 0 (s) + Cu 2+ (aq) + SO 4 2-  Cu 0 (s) +

Lesson 2. Galvanic Cells In the reaction between Zn and CuSO 4, the zinc is oxidized by copper (II) ions. Zn 0 (s) + Cu 2+ (aq) + SO 4 2-  Cu 0 (s) +

Similar presentations

Ads by Google