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Mass Flow Analysis of Chromium and Chromium Compounds
Disposal of chromium and chromium compounds mainly takes place in connection with
disposal of products and waste products which contain chromium. Chromium is an element and
so will not disappear. This means that we cannot dispose of chromium by disposing of
products which contain chromium – we merely move it.
Once an object, a product, has been used for the last time, it can either be disposed
of actively or simply "perish" where it was last used. In both cases, the
contents of such products may enter the environment. This includes chromium. Active
disposal allows some control over emissions into nature.
When we dispose of chromium, we often do so in the form of relatively small
concentrations in other products: tapes, chromium plated objects, impregnated wood,
painted objects, glass, etc.
The only known way to release chromium from the product it occurs in is to burn or melt
it.
Active disposal includes the following forms of waste treatment:
 | Landfilling (in principle, this is restricted to non-flammable objects) |
| Incineration (flammable objects) |
| Treatment plants (municipal), application of sludge to agricultural areas |
| Treatment plants (at industries) |
| Special waste (Kommunekemi) |
| - Incineration |
| - Landfilling |
Passive disposal occurs when products which contain chromium are left to perish
where they were last used. It is estimated that this type of disposal is quite infrequent
in Denmark. There will, however, probably be some minor losses of chromium to the
environment from products which contain chromium and which perish without being sent for
incineration or landfilling, e.g. impregnated wood, painted objects (due to peeling) and
chromium plated objects (due to oxidation). The quantities released in this manner have
not been assessed.
A number of products containing chromium can be recycled or reused. This
means that the products remain usable for longer, which in turn means that the production
of new goods of this kind can be reduced. Metal and glass are prime examples of products
which can be recycled or reused and which contain significant amounts of chromium. Plastic
and paper are also recycled, however, and may contain chromium from pigments, etc. The
most significant recyclable material flows which contain chromium are:
| Iron and steel |
| Aluminium |
| Copper |
As metallic chromium occurs as part of other metals, it is also recycled along with
those metals – primarily stainless steel, steel, iron, aluminium and copper. When
products made from these metals are worn out, they are collected for recycling, and of
course the chromium in such metals will be included in this recycling.
The quantities of metal collected in Denmark can be described as being equal to the
net export of scrap metal plus metal recycled in Denmark plus losses from reprocessing.
In a life cycle analysis of steel, it is estimated that the scrap industry collects 97%
of all steel scrap in Denmark (Kjeldahl, 1991, p. 103). In a new study prepared by DEMEX
and others, it is estimated that 90% of all stainless steel in the building sector is
reused, while the remaining 10% is disposed of by means of landfilling (5%) and
incineration (5%). The study also estimates that 95% of all painted surfaces are disposed
of by means of incineration, while the remaining 5% are sent to landfills (Lauritzen et
al., 2002). Stainless steel is sent for re-melting in Sweden (Kjeldahl, 1991, p. 106).
Table 5.1
Recycling of iron and scrap metal in 1999 (The Danish EPA, 2000).
|
Quantity, 1000 tonnes |
Iron and scrap metal from Denmark sent to
foundries and Stålvalseværket |
417 |
Iron and scrap metal exported by scrap
dealers |
570 |
Iron and scrap metal imported by scrap
dealers |
22 |
Total recycled Danish iron and scrap
metal |
965 |
Iron and scrap metal imported by
Stålvalseværket and foundries |
230 |
According to Statistics Denmark, a total of 965,000 tonnes scrap metal is recycled in
Denmark each year. In 1999, a total of 987,000 tonnes scrap metal was collected in
Denmark. If we assumed that this corresponds to 97% of the total amount of scrap metal,
this means that 3% – or 31,000 tonnes scrap metal – ends up in the environment.
It is estimated that much of this scrap metal is iron with an average chromium content of
approximately 0.05–0.1%. This means that 15.5–31 tonnes metallic chromium ends
up in the environment, primarily in the soil.
Stålvalseværket and other Danish foundries do not accept stainless steel. As a
result, we can safely assume that the 570,000 tonnes sent for export contain large amounts
of stainless steel. As the exact figures are not known, it is estimated that stainless
steel accounts for approximately 25%. This corresponds to 142,500 tonnes stainless steel
or 24,000–26,000 tonnes chromium. It is assumed that the percentages stated for
recycling of stainless steel within the building industry also apply to Denmark as a
whole.
This means that approximately 2,700–2,900 tonnes chromium end up at landfills.
Half of this chromium has passed through an incineration plant first.
By consulting the updated mass flow analysis for aluminium (see section 2.2), we
can see that 18,600–22,300 tonnes of aluminium are recycled in Denmark each year.
This corresponds to 4–22 tonnes chromium. Aluminium will be reprocessed by means of
re-melting. The chromium content of the reprocessed material will not be any different
from that of the source material. The total net export of scrap aluminium is
8,000–17,000 tonnes, corresponding to 2–18 tonnes of chromium.
By consulting the updated mass flow analysis for copper (see section 2.3), we can
see that 9,000–10,000 tonnes of copper are recycled in Denmark each year. This
corresponds to 2–3 tonnes chromium. Copper is reprocessed by means of re-melting. The
chromium content of the reprocessed material will not be any different from that of the
source material. The total net export of scrap copper is 15,000–24,000 tonnes,
corresponding to 4–6 tonnes of chromium. The exported scrap is often reprocessed by
means of electrolytic refining, which reduces or removes the chromium in the copper.
Various types of waste are actively disposed of. This concerns waste from
households, industry, the building sector, etc. The waste statistics include figures on
disposal of solid waste.
Table 5.2
Waste Statistics 1999 (The Danish EPA, 2000).
|
Quantities in 1999, 1000 tonnes |
Households |
2,963 |
Refuse |
1,665 |
Bulky waste |
672 |
Garden waste |
464 |
Other |
163 |
Institutions / retail, offices |
955 |
Production companies, etc. |
2,653 |
Building and construction |
2,968 |
Treatment plants |
1,379 |
Clinker, fly ash, etc. (coal) |
1,299 |
Other |
15 |
Total |
12,233 |
In 1999, Denmark exported significant amounts of waste.
Table 5.3
Export of waste from Denmark in 1999 (The Danish EPA, 2000).
|
Quantities in tonnes |
Glass |
12,400 |
Plastics |
19,700 |
Iron and metal |
403,700 |
Other flammable goods |
8,100 |
Fly ash and clinker from coal-fired CHP
plants |
146,200 |
Slag and flue remediation products from
iron production |
11,000 |
Flue gas remediation products from waste
incineration plants |
56,400 |
Scrap iron from waste incineration plants |
10,700 |
Other registered waste |
58,800 |
In 1999, Denmark imported waste corresponding to 4% of the domestic waste production. This
imported waste was, however, mainly "green" waste or metal and was exclusively
intended for recycling or incineration. Except for the chromium content in the 252,000
tonnes scrap iron and metal imported for recycling, it is estimated that no significant
quantities of chromium are imported with waste.
In Denmark, all the waste that can be burnt is burnt. The quantities of chromium sent
for incineration are calculated to be;
| Impregnated wood: 3.8 tonnes Cr/year |
| Discarded leather: 106–236 tonnes Cr/year |
| Discarded textiles: 5.1–15.3 tonnes Cr/year |
| Discarded chromium plated products: 2.9 tonnes Cr/year |
| Discarded electronic storage media: 1.8–2.6 tonnes Cr/year |
Waste incineration gives rise to some residual products. These are slag, bottom ash,
boiler slag, economizer ash, fly ash and flue gas cleaning products. Table 5.4 shows
estimates of the quantities involved.
Table 5.4
Quantities of residual products caused by waste incineration (Hjelmar & Hansen,
2002).
Residual product |
Kg/tonne incinerated waste |
Slag |
250–400 |
Bottom ash |
5 |
Boiler slag |
2–10 |
Fly ash |
10–30 |
Flue gas cleaning, dry
process |
20–50 |
Flue gas cleaning, semi-dry
process |
20–40 |
Flue gas cleaning, wet
process |
1–3 |
Table 5.5 shows the chromium content of the most important residual products. Assuming
that a total of 2,929,000 tonnes waste is incinerated each year (The Danish EPA, 2000), we
can estimate the total amount of chromium in residual products from waste incineration.
Table 5.4
Chromium content in residual products from waste incineration (Hjelmar &
Thomassen, 1992; Hjelmar & Hansen, 2002).
Residual product |
Chromium concentration
(mg/kg) |
Chromium quantity
(tonnes/year) |
Fly ash |
650 |
19–57 |
Flue gas cleaning products from dry and
semi-dry processes, with fly ash |
180 |
18–47 |
Sludge from wet flue gas cleaning |
240 |
0.7–2.1 |
Slag |
230–600 (415) |
119–312 |
|
|
158–418 |
For 1995–1996, the emission factors for waste incineration plants equipped with
various clean-up technologies have been set at 0.1–1.7 g Cr/tonne waste (Illerup et
al., 1999). This makes for an emission of chromium to air of 0.3–5.0 tonnes. Only
small amounts of waste (approximately 2%) were treated at the plant with the high emission
factor in 1996/1996, so a more realistic estimate would be emissions to air of
0.3–1.5 tonnes chromium.
Some waste cannot be incinerated and is deposited along with non-recyclable
residual products from incineration of waste and combustion of fossil fuels (coal). Table
5.6 shows the quantities deposited at landfills in 1999. Some dangerous waste is also
deposited at landfills. For example, sludge from the chromium plating industry –
which contains a great deal of chromium – is deposited with Kommunekemi. In 1999,
approximately 106 tonnes of chromium were deposited with Kommunekemi. It should be noted
that a very significant amount (99%) of all fly ash from coal incineration was recycled in
1999. Larger quantities than this have been deposited at landfills in other years.
Table 5.6
Waste deposited at landfills (The Danish EPA, 2000).
|
Quantity |
Deposited fraction |
tonnes/year |
Waste, excluding slag and fly ash |
1,460,000 |
Slag, waste |
92,302 |
Fly ash, waste |
43,102 |
Sludge, dry matter, long-term depots |
47,441 |
Clinker and fly ash, coal |
12,990 |
If we use the Cr concentrations for slag and fly ash given in Table 5.5 and combine them
with estimated contents in residual products from coal combustion (Hjelmar & Thomasen,
1992), we can calculate the quantities of chromium deposited at landfills. This figure
does not, however, include the quantities deposited with standard non-flammable waste. No
information on the chromium contents of standard non-flammable waste deposited at
landfills is available from either Waste Centre Denmark or the Household Waste department
within the Danish EPA.
Table 5.7
Chromium deposited at landfills
|
Quantity |
Deposited with fraction |
Tonnes Cr/year |
Waste, excl. slag and fly ash |
unknown |
Slag, waste |
38 |
Fly ash, waste |
28 |
Sludge, dry matter |
2 |
Clinker and fly ash, coal |
1 |
Total |
69 |
Some chromium may enter the environment from landfills and in connection with leaching
percolate. This issue is not addressed here.
All in all, it is estimated that approximately 175 tonnes chromium is deposited at
landfills each year. This figure does not include all the deposits made in the form of
standard non-flammable waste.
Parts of the organic fraction of refuse and green waste from gardens, parks, etc.
undergo biological treatment. Such waste ends up as compost or as residual products from
biogas generation. Due to their nutrient content, these residual products are applied to
agricultural soil. In addition to nutrients, however, they also contain various heavy
metals, including chromium. The table below shows the chromium content in the residual
products and the annual chromium input from residual products to agricultural soil.
Table 5.8
Average chromium contents and annual total chromium quantities in compost and residual
products from biogas generation (The Danish Forest and Nature Agency, 1998).
Residual product type |
Chromium content
mg/kg dry matter |
Annual quantity
Tonnes dry matter |
Chromium quantity
kg/year |
Compost from refuse |
16 |
6,000 |
1.9 |
Compost from garden and park waste |
9.1 |
130,000 |
47 |
Liquid residual product from biogas
generation |
5.6 |
56,500 |
37 |
Total quantities |
|
192,500 |
86 |
Chemical waste/dangerous waste is disposed of through approved specialists, including
Kommunekemi. Table 5.9 illustrates the disposal of fractions of dangerous waste which may
contain chromium. No chromium analyses of the individual waste fractions are available.
Table 5.9
Disposal of dangerous waste in 1999; fractions which may contain chromium (The Danish
EPA, 2000).
Fraction |
Recycling
tonnes |
Incine- ration
tonnes |
Land- filling
tonnes |
Special treat- ment
tonnes |
Total
tonnes |
Dyes/Varnishes/Paint containing organic
solvents |
14 |
10,640 |
2 |
815 |
11,471 |
Dyes/Varnishes/Paint without organic
solvents |
|
6,572 |
7 |
824 |
7,403 |
Organic metal compounds, except Hg |
|
112 |
|
1 |
113 |
Acid aqueous solutions containing
chromium compounds |
855 |
95 |
4 |
419 |
1,373 |
Photographic development baths |
3,051 |
1,116 |
10 |
60 |
4,237 |
Photo-process baths containing chromium |
|
7 |
|
|
7 |
Fixative baths |
1,293 |
20 |
|
963 |
2,276 |
Metal hydroxide and oxide sludge |
1,266 |
1,306 |
3,683 |
145 |
6,400 |
Smoke scrubber sludge and smoke filter
dust from iron and metal foundries |
|
369 |
743 |
203 |
1,315 |
Dye works waste |
|
2 |
|
|
2 |
Watery sludge from pressure-treatment of
wood |
|
14 |
|
7 |
21 |
Salts for hardening |
|
15 |
|
52 |
67 |
Pharmaceutical waste |
|
728 |
|
557 |
1,285 |
Chemicals from laboratories, etc. |
1 |
1,056 |
54 |
67 |
1,178 |
Filter dust from flue gas cleaning |
11,002 |
|
|
|
11,002 |
Fly ash |
376 |
|
5771 |
22,413 (stored) |
28,560 |
Flue gas cleaning products |
5,170 |
|
37,434 |
7,183 |
49,787 |
Kommunekemi collects samples of their output every six months. In 1999, they had the
following output (Kommunekemi, 2002b):
| 11,529 tonnes of slag with a chromium content of 120–210 mg/kg, corresponding to
1.4–2.4 tonnes chromium |
| 5,472 tonnes residual products (fly ash, etc.) with chromium contents of 250–680
mg/kg, corresponding to 1.4–3.7 tonnes chromium |
| 3,437 tonnes filter cake (from in-house treatment at Kommunekemi) with a chromium
content of 7.500 mg/kg, corresponding to 26 tonnes chromium |
| 3,579 tonnes filter cake from others (typically galvanic industries with in-house
treatment plants) with a chromium content of 21,000 mg/kg, corresponding to 75 tonnes of
chromium. |
The 100–110 tonnes of residual products, etc., are deposited at landfills
(Kommunekemi, 2002b).
In 1999, a total of 3.782 kg chromium(VI) was leached with percolate. This figure is
above average due to the unusually high rainfalls in 1999. The corresponding figures for
2000 and 2001 are 0.492 kg and 1.478 kg. The landfill is located close to the coastline,
which ensures that the leached chromium(VI) cannot reach the groundwater (Kommunekemi,
2002b).
During a period in 1996, studies were made in the towns Bagsværd and Skovlunde of
xenobiotic substances in the run-off from built-up areas. Here, concentrations of
10.6–18.5 µg Cr/L were measured (Kjølholt et al., 1997). These levels
correspond to those found in the input to a number of treatment plants.
Table 5.10
Inflow to specific treatment plants 1997 (Jepsen & Grüttner, 1997)
|
Average concentration, µg Cr/L |
IS Avedøre Kloakværk |
28 |
Renseanlæg Damhusåen |
19 |
Herning Centralrenseanlæg |
47 |
In 1999, the average concentration of chromium in inflow to the "Lynetten"
treatment plant was 7.8 µg/L, while the corresponding figure for "Damhusåen"
was 8.9 µg/L. On average, the total input was 1.4 kg Cr/day to "Lynetten" and
0.7 kg/day to "Damhusåen" (Lynettefællesskabet I/S, 2000). The total amount of
water treated in 1999 was in the region of 825 million m3. If we take this
information as the basis for assuming an average content of 5–10 µg Cr/L, the
average inflow to treatment plants is 4.1–8.3 tonnes Cr/year. As we can see, these
figures correspond well to the quantities found in sludge. In previous studies, it has
been estimated that 80% of the chromium is transferred to the sludge at treatment plants
(Grüttner & Jacobsen, 1994). If we assume that 80% is held back at the plants, we
arrive at a discharge from treatment plants into the aquatic environment of 1.2 tonnes
Cr/year. The Danish EPA states that discharges into the aquatic environment from specific
industrial contributors is 0.219 tonnes Cr/year, possibly more (The Danish EPA, 1999b).
In 1999, a total of 1,409 treatment plants were registered in Denmark. These plants
treat wastewater corresponding to 8.09 million person equivalents (PE). In 1999, the
plants produced 155, 621 tonnes sludge (dry matter). That year, the limit value for
chromium in sludge was 200 mg/kg total phosphorus (P) or 100 mg/kg sludge (dry matter). In
1999, the weighted average concentrations of chromium in sludge were 33.2 g Cr/tonnes
sludge (dry matter) for all sludge, and 24.6 g Cr/tonne sludge (dry matter) for sludge
applied to agricultural soil (The Danish EPA, 2001). This corresponds to a total content
of 4.9 tonnes Cr in the sludge, of which 2.1 tonnes were applied to agricultural soil. The
chromium which was not applied to agricultural soil was sent for incineration
(approximately 45%) or to landfills (approximately 51%) (The Danish EPA, 2001b). This
means that 1.3 tonnes chromium from sludge is sent for incineration each year, and that
1.4 tonnes chromium from sludge is deposited at landfills each year.
As has been demonstrated elsewhere, large amounts of chromium are emitted to air in
connection with combustion of fossil fuels and incineration of waste.
Table 5.11
Emissions of heavy metals to air in 1999
(National Environmental Research Institute, Denmark, 2002).
|
kg Cr/year |
Combustion – CHP plants and
refineries |
1,410 |
Combustion – dwellings and
institutions |
191 |
Combustion – industry |
805 |
Production processes |
0 |
Road transport |
179 |
Other mobile sources |
65 |
Total |
2,650 |
Some of these emissions are caused by chromium contents in fuel.
Based on statistics from 7 stations, it has been ascertained that the bulk deposition
of chromium onto Danish soil is 125 µg Cr/m2 each year. This does not include
aerosol deposition, which may correspond to 5–20% of the bulk deposition.
The total annual contribution to Danish soil (43,000 km2) from atmospheric
deposition is estimated to be 10 tonnes Cr (average for the last 10 years).
As regards Danish waters, approximately 167 µg Cr/m2 falls on the Danish
inland waterways (40,000 km2) each year. This corresponds to a total of 7
tonnes per year (Hovmand et al., 2000).
Chromium emissions associated with waste treatment can be summarised as shown in Table
5.12.
Table 5.12
Chromium emissions associated with waste treatment in Denmark, 1999.
Process/source |
Air
tonnes |
Water
tonnes |
Soil
tonnes |
Landfills
tonnes |
Total
tonnes |
Recycling |
|
0.2–2 |
16–32 |
2,700–2,900 |
2,716–2,932 |
Waste incineration |
0.3–1.5 |
– |
– |
36–96 |
36–98 |
Biological waste treatment |
– |
– |
0.1 |
– |
0.1 |
Waste deposit |
– |
? |
– |
– |
– |
Chemical waste / Dangerous waste |
|
0.5–3.5 |
– |
100–110 |
101–114 |
Wastewater |
– |
1.2 |
– |
– |
1.2 |
Wastewater sludge |
– |
– |
2.1 |
1.4 |
3.5 |
Chromium is not recycled in pure form in Denmark. Instead, it is recycled as part
of iron, steel, aluminium and copper. The quantities of recycled chromium can be
calculated as follows: 2,600–3,600 tonnes chromium with iron and steel, 7–22
tonnes chromium with aluminium, and 2–3 tonnes chromium with copper. Recycling of
chromium as part of residual products (fly ash and clinker) from coal-fired CHP plants
accounts for 62–185 tonnes Cr/year. Chromium compounds are not recycled as part of
products. They can, however, be extracted from wastewater from relevant processes, e.g.
chromating.
Chromium enters the waste treatment system with household waste as well as
commercial waste. No statistics on chromium in inflows to the various plant types are
available, but more information is available on the outputs. For example, residual
products from waste incineration plants (fly ash, residual products containing fly ash
from flue gas cleaning, sludge, and slags) represent chromium quantities of 158–418
tonnes per year, while the emission to air can be estimated at 0.3–1.5 tonnes
chromium. In 1999, a total of 77% of the residual products (corresponding to 122–322
tonnes chromium) was recycled, while the remaining quantities (corresponding to 36–96
tonnes chromium) were deposited at landfills.
Several waste fractions containing chromium are classified as dangerous waste. This
means that they must be disposed of through approved specialists such as Kommunekemi. No
analyses of inputs to Kommunekemi are available, but chromium contents have been
determined for a number of residual products (e.g. clinker, filter cakes, etc.) deposited.
A total of 100–110 tonnes residual products containing chromium is deposited.
Chromium contents have been identified in samples of inflow to three treatment plants.
On the basis of concentrations of 19–47 µg Cr/L, the total input of chromium to
wastewater treatment plants can be estimated to be 4.1–8.3 tonnes Cr/year. Of this
amount, approximately 80% is held back. The emissions/discharges into the aquatic
environment are estimated to be 1.2 tonnes Cr/year. The remaining quantities are caught in
sludge. With a chromium concentration in sludge of 33.2/tonne dry matter (average for all
sludge) and 24.6 g/tonne dry matter in sludge for application to agricultural soil, we
arrive at an output of 4.9 tonnes chromium. Of this amount, 2.1 tonnes were applied to
agricultural soil, 1.3 tonnes were sent for incineration, and 1.4 tonnes were deposited at
landfills.
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