7/23/2019 Colour Facts Sheet

http://slidepdf.com/reader/full/colour-facts-sheet 1/4

PHYSICAL AND CHEMICAL CHARACTERISTICS –

FACT SHEETS

Australian Drinking Water Guidelines Version 2.0 Updated December 2013 548

Colour (True)(endorsed 1996)

GUIDELINE

 Based on aesthetic considerations, true colour in drinking water should not exceed 15 HU.

GENERAL DESCRIPTION

Two terms are used to describe colour. ‘True colour’ is the colour after particulate matter has been

removed (usually by filtration through a 0.45 micrometer pore size filter). ‘Apparent colour’ is what one

actually sees; it is the colour resulting from the combined effect of true colour and any particulate matter,

or turbidity. In turbid waters, the true colour is substantially less than the apparent colour.

In natural waters, colour is due mainly to the presence of dissolved organic matter including humic andfulvic acids, which originate from soil and decaying vegetable matter. Surface water can also be coloured

by waste discharges, for example from dyeing operations in the textile industry, and paper manufacture.

The dissolution of metals in pipes and fittings can also discolour drinking water. Badly corroded iron

pipes can produce a brownish colour whereas corrosion of copper pipes can produce a blue-green

colouration on sanitary ware and a faint blue colour in water in extreme cases. The condition of

household pipes can significantly influence water colour.

In bore water, ‘red water’ is a frequent problem, caused by the oxidation of iron. In addition, a

black discolouration in reservoirs and distribution systems can result from the action of bacteria on

dissolved manganese to produce insoluble oxides. Some of these compounds form fine suspensions,

or are only partially dissolved, and so contribute to apparent rather than true colour. (See Section 5.6 Nuisance organisms .)

 As a guide, tea has a colour of about 2500 Hazen units (HU, see below). A true colour of 15 HU can

be detected in a glass of water, and a true colour of 5 HU can be seen in larger volumes of water, for

instance in a white bath. Few people can detect a true colour level of 3 HU, and a true colour of up to

25 HU would probably be accepted by most people provided the turbidity was low. Some examples of

drinking water with differing turbidity and colour are shown in Plate 1.

True colour is preferred analytically, as the measurement is more precise than for apparent colour, and

not as dependent on site or time. If both true colour and turbidity are at the guideline values (i.e. true

colour of 15 HU and turbidity of 5 NTU[Nephelometric Turbidity Units]), the apparent colour could be

20 HU. This is considered to be acceptable.

 Variations in colour are likely to lead to more complaints than a high but consistent colour.

TYPICAL VALUES IN AUSTRALIAN DRINKING WATER

In major Australian reticulated supplies true colour ranges from 1 HU to 25 HU for filtered or fully treated

supplies, and from 1 HU to 85 HU for unfiltered supplies.

MEASUREMENT

Colour can be measured spectrophotometrically or using a visual comparator. In both cases, the standard

unit of measurement is the Hazen unit (HU). (True colour is often quoted as True Colour Units, or TCU;however, the numerical values are identical.) Hazen units are defined in terms of a platinum–cobalt

7/23/2019 Colour Facts Sheet

http://slidepdf.com/reader/full/colour-facts-sheet 2/4

Fact Sheets Physical and Chemical Characteristics

NOTE: Important general information is contained in PART II, Chapter 6

Australian Drinking Water Guidelines Version 2.0 Updated December 2013 549

standard (APHA Method 2120B 1992). This standard was developed for the analysis of colour in natural

 waters with a yellow-brown appearance, and is not applicable to waters with different colours.

It is advisable to record the pH with the colour measurement, as the colour of natural surface waters

increases with pH.

Colour values obtained using a spectrophotometer are dependent on the wavelength used for the

measurement. There is no standard wavelength used in Australia, but values ranging from 395 nm

to 465 nm are generally used. In the absence of a suitable Australian Standard, the British Standard,

 which uses 436 nm (BSI Method BS6068 1986), is suitable.

TREATMENT OF DRINKING WATER

Constituents of natural colour derived from humic and fulvic acids can be reduced by coagulation

followed by filtration (AWWA 1990). Oxidation by chlorine or ozone will also reduce colour but may

produce undesirable by-products.

HEALTH CONSIDERATIONS

Colour is generally related to organic content, and while colour derived from natural sources such as

humic and fulvic acids is not a health consideration, chlorination of such water can produce a variety

of chlorinated organic compounds as by-products (see Section 6.3.2 on disinfection by-products). If the

colour is high at the time of disinfection, then the water should be checked for disinfection by-products.

It should be noted, however, that low colour at the time of disinfection does not necessarily mean that

the concentration of disinfection by-products will be low.

Reactions between naturally occurring humic and fulvic material and water disinfectants (such as

chlorine, ozone, chloramines and chlorine dioxide) can also cause difficulties in maintaining an adequate

level of disinfectant, thus creating the opportunity for bacterial reinfection or regrowth.

The solubility of some organic pollutants can also be increased through complex formation with

humic material.

Coloured water may prompt people to seek other, perhaps less safe, sources of drinking water.

DERIVATION OF GUIDELINE

The guideline value is based on the colour that is just noticeable in a glass of water. This is generally

accepted as being 15 HU.

GUIDELINES IN OTHER COUNTRIES

The Canadian Guidelines and the 1984 World Health Organization (WHO) Guidelines both recommend

a value of 15 HU. The 1993 WHO Guidelines indicate that a colour above 15 TCU may give rise to

consumer complaints.

The United States EPA Secondary Drinking water Regulations have a maximum concentration for colour

of 15 HU.

The European Economic Community Standards for colour are a maximum admissible value of 20 HU and

a guideline value of 1 HU.

7/23/2019 Colour Facts Sheet

http://slidepdf.com/reader/full/colour-facts-sheet 3/4

Fact Sheets Physical and Chemical Characteristics

NOTE: Important general information is contained in PART II, Chapter 6

Australian Drinking Water Guidelines Version 2.0 Updated December 2013 550

REFERENCES

 APHA Method 2120B (1992). Colour: Visual comparison method. Standard Methods for the Examination

of Water and Wastewater, 18th edition. American Public Health Association, Washington.

 AWWA (American Water Works Association) (1990). Water Quality and Treatment: A handbook ofcommunity water supplies . AWWA, 4th edition, McGraw-Hill Inc.

BSI Method BS6068 (1986). Examination and determination of colour. British Standards Institution, British

Standard for Water Quality, Section 2.22.

 WHO (World Health Organization) (2006). Guidelines for Drinking-water Quality . 3rd Edition, WHO,

Geneva, Switzerland.

7/23/2019 Colour Facts Sheet

http://slidepdf.com/reader/full/colour-facts-sheet 4/4

Fact Sheets Physical and Chemical Characteristics

NOTE: Important general information is contained in PART II, Chapter 6

Australian Drinking Water Guidelines Version 2.0 Updated December 2013 551

Colour and Turbidity 

1. Colour = 5 HU

Turbidity = 1 NTU

2. Colour = 5 HU

Turbidity = 5 NTU

3. Colour = 15 HU

Turbidity = 5 NTU

4. Colour = 15 HU

Turbidity = 1 NTU