How can hardness in water
be removed?
Temporarily hard water is made by bubbling carbon dioxide through limewater for
some time. Temporarily and permanently hard water are boiled,
have sodium carbonate added and are subjected to ion
exchange. The hardness of the solutions, before and after, is tested
using soap solution.
Lesson
organisation
This
experiment is designed as a combination of demonstration and class practical
work. The making and boiling of temporarily hard water is best done on a larger
scale than in a test-tube, and ion exchange columns are tedious to set up in
quantity. Also, the students already have a bewildering array of colourless
solutions with which to deal. Adding more might cause some to get very
confused. With small groups, however, the preparation and boiling of
temporarily hard water and the ion exchange could be done by the students.
If the
suggested method here is used, the beakers of solutions should be
labelled A to F and each should have a
dropping pipette. Students should bring up their test-tube racks and move along
the solutions, placing 1 cm depth of each solution in the corresponding
test-tube.
Do not
let them mix the dropping pipettes nor move the stock bottles around.
The
demonstration plus the student practical will take about one hour.
Chemicals
The teacher will require:
Calcium
sulfate solution, 300 cm3 (Note 4)
Limewater
(IRRITANT), 150 cm3
Sodium
zeolite, about 5 g (Note 2),
Marble
chips
Dilute
hydrochloric acid, 2 M (IRRITANT)
Each student or group of students will need:
Solutions
labelled as shown below, 100 cm3 each
A
Temporarily hard water*
B
Permanently hard water (Note 4)
C
Temporarily hard water that has been boiled and filtered*
D
Temporarily hard water that has passed through an ion exchange column*
E
Permanently hard water that has passed through an ion exchange column*
F
Distilled water (or deionised water)
* These
are prepared by the teacher in the demonstration part of the experiment
Soap
solution in IDA (Industrially Denatured Alcohol) (HIGHLY FLAMMABLE, HARMFUL),
10 cm3 (Note 5)
10 cm3 (Note 5)
Sodium
carbonate-10-water (IRRITANT), about 1 g
Apparatus
The teacher will require:
Eye
protection
Beakers
(500 cm3), 3
Bunsen
burner
Tripod
and gauze
Heat
resistant mat
Vacuum
filtration apparatus (Note 1)
Ion
exchange apparatus (Note 2)
Gas
generator for carbon dioxide (Note 3), or a CO2 cylinder
Each student or group of students will need:
Test-tubes,
9
Test-tube
rack
Labels,
for test tubes
Beaker
(100 cm3)
Dropping
pipette
Spatula
Health
& Safety and Technical notes
Wear eye
protection throughout.
Calcium
sulfate, CaSO4.2H2O(s) - see CLEAPSS Hazcard.
Limewater
(calcium hydroxide solution), Ca(OH)2(aq), (treat as
IRRITANT) - see CLEAPSS Hazcard and CLEAPSS
Recipe Book.
Sodium
zeolite
Sodium
carbonate-10-water, Na2CO3.10H2O(s), (IRRITANT) -
see CLEAPSS Hazcard.
Marble
chips (calcium carbonate), CaCO3(s) - see CLEAPSS Hazcard.
Hydrochloric
acid, (IRRITANT) - see CLEAPSS Hazcard and CLEAPSS Recipe
Book.
1 Vacuum
filtration apparatus. See CLEAPSS Laboratory Handbook.
2 Ion
exchange apparatus. The sodium zeolite should be soaked in deionised water for
24 hours before use. (Dry resin would expand and crack the tube). A cotton wool
plug should then be placed at the bottom of a tube with a tap* and the resin
added (as a slurry) above the cotton wool. The resin must be kept covered in
deionised water until the column is required. Some hard water is poured into
the tube above the deionised water and the tap is opened. More hard water is
added as the softened water is collected in a beaker below the tap.
* a
burette will do, provided the tap is removable, allowing the cotton wool plug
to be pushed out with a rod.
3 Gas
generator for carbon dioxide. See Standard Techniques:
4 Calcium
sulfate solution. Stir a spatula or two of calcium sulfate dihydrate into
distilled water until no more will dissolve (it is not very soluble). Allow to
stand and decant off the clear, saturated solution. Dilute it with an equal
volume of distilled or deionised water to make the stock solution of
permanently hard water.
5 Soap
solution in ‘ethanol’ (Industrial Denatured Alcohol, IDA – see CLEAPSS Hazcard
(HIGHLY FLAMMABLE, HARMFUL) can be purchased or made up – see CLEAPSS Recipe
Book.
Procedure
Demonstration
a Dilute about 150 cm3 of limewater with an equal volume of distilled or deionised water. Pass in carbon dioxide, taking care that the gas carries over no acid spray (from the reaction between the marble chips and the acid). A milky precipitate of calcium carbonate soon forms. Continue the passage of gas until all the precipitate dissolves, giving a solution of calcium hydrogencarbonate. This is temporarily hard water.
a Dilute about 150 cm3 of limewater with an equal volume of distilled or deionised water. Pass in carbon dioxide, taking care that the gas carries over no acid spray (from the reaction between the marble chips and the acid). A milky precipitate of calcium carbonate soon forms. Continue the passage of gas until all the precipitate dissolves, giving a solution of calcium hydrogencarbonate. This is temporarily hard water.
b Place
about half of the temporarily hard water in a beaker and boil it for about 5
minutes. Filter, using vacuum filtration apparatus.
c Scrape
some of the solid residue from b into a test-tube and add
dilute hydrochloric acid. Fizzing should show that the solid is a carbonate
(calcium carbonate).
d Boil
about the same quantity of permanently hard water (to that used in b)
in another beaker. Show that there is no precipitate. Allow the solution to
cool until it is safe to handle.
e Set
up two ion exchange columns containing sodium zeolite (see note 3).
Pour about half of the temporarily hard water from a through one
column and collect the solution in a beaker. Repeat with the other ion exchange
column using an equal volume of permanently hard water.
Class
experiments
a Set up six test tubes in a rack, labelled A – F, containing about 1 cm depth of
a Set up six test tubes in a rack, labelled A – F, containing about 1 cm depth of
A Temporarily hard water
B Permanently hard water
C Temporarily hard water that has been boiled and filtered
D Temporarily hard water that has passed through an ion exchange column
E Permanently hard water that has passed through an ion exchange column
F Distilled or deionised water
B Permanently hard water
C Temporarily hard water that has been boiled and filtered
D Temporarily hard water that has passed through an ion exchange column
E Permanently hard water that has passed through an ion exchange column
F Distilled or deionised water
b Collect
10 cm3 of soap solution in a small beaker.
c Add
a drop of soap solution to tube A. Stopper the tube and shake it.
If no lather (foamy bubbles) appear, add another drop, stopper and shake again.
Continue until a lather appears that lasts for 5 seconds or longer. Count the
number of drops that you have used. Note the appearance of the water in the
test-tube.
d Repeat
the procedure in c for tubes B to F.
e In
another test-tube, take a fresh sample of any of one of the water samples that
were ‘hard’ (that is, those that took a lot of soap to achieve a lather). Add
half a spatula measure of sodium carbonate crystals to the test-tube and shake
it. Observe the contents of the test-tube. Now repeat the procedure in c to
see how many drops of soap solution are required to produce a lather. Note the
new number of drops.
f Repeat
the procedure in e for any other water samples that were
‘hard’.
Teaching
notes
A and B should
require a lot of drops of soap solution, while the others should not require
many at all. A and B contain dissolved
calcium salts that react with soap solution to form an insoluble ‘scum’ that
should be seen as a white cloudiness in the tubes or as specks floating on the
surface of the water:
calcium
salt(aq) + sodium stearate (soap)(aq) → calcium stearate (scum)(s) + sodium
salt(aq)
Only when
all the calcium ions have been precipitated out as scum will the water lather.
Thus hard water wastes soap as well as causing unsightly deposits on baths and
showers.
Temporarily
hard water is defined as that which can be softened by boiling. The reactions
by which it is made here are:
Ca(OH)2(aq) + CO2(g) → CaCO3(s) + H2O(l)
(Calcium
carbonate is the ‘milkiness’ that forms when limewater is reacted with carbon
dioxide)
CaCO3(s) + CO2(g) + H2O(l) → Ca(HCO3)2(aq)
This
reaction also occurs when rain water (containing dissolved carbon dioxide)
flows over limestone rocks. On boiling, the reaction is reversed:
Ca(HCO3)2(aq) → CaCO3(s) + CO2(g) + H2O(l)
The
calcium carbonate shows as a white cloudiness (precipitate) when the
temporarily hard water is boiled. The water does not now contain any dissolved
calcium salts, so it is no longer hard.
This
solid calcium carbonate is ‘limescale’ that wastes energy if it forms in
boilers and kettles and can be dangerous if it blocks pipes or washing
machines.
Hard
water of both types can also be softened by:
- exchanging
sodium ions for the calcium ions – these stay on the zeolite resin. This
resin is a lattice with negative charges attached. These hold the positive
ions. The attachment of the positive ions to the resin is reversible. The
resin can be ‘regenerated’ by treating it with concentrated sodium
chloride solution.
- adding
sodium carbonate. This precipitates out the calcium ions as insoluble
calcium carbonate:
eg CaSO4(aq) + Na2CO3(aq) → CaCO3(s) + Na2SO4(aq)
The
calcium carbonate is once again seen as a white cloudiness.
‘Bath
salts’ often contain sodium carbonate (as well as perfume etc) and this softens
the water.
- ‘complexing’
the calcium ions – ie adding large anions that form a ‘complex’ with the
calcium ions and stop them reacting with soap to form scum. Water
softeners such as ‘Calgon’ work this way. The chemistry of complex ions is
beyond the intermediate level, however.
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