Livscyklusvurdering af 3 typer metalmaling

3. Summary

This report contains an inventory and an assessment of environmental impacts and occupational health impacts at manufacturing, use and end disposal of a powdered paint, a solvent based paint and a water based paint.

Paints with a specific recipe have not been chosen. On the contrary, average paints were selected, where the "recipe" consists of an average of all recipes produced for each of the 3 main types over 1 year, at the factory Technos Schou A/S.

Manufacturing phase

The inventory of the environmental impact in the manufacturing phase is based on an environmental screening of TEKNOS SCHOU A/S made in the period from January 23, 1995 till February 6, 1996.

As the environmental data from this screening are allocated to processes connected to the manufacturing of the 3 types of paint, they can be converted to environmental impact per each tonne of product. Environmental impacts, such as consumption of electricity for lighting and administration, are allocated on the 3 types of paint according to the value of the product.

Utility phase

As the examined paints are all hardened in an oven, the environmental impact in the utility phase will primarily be impacts from the painting process, as drying in the oven ensures that no volatility of solvents will follow when the painted product is being used.

The inventory of the environmental impact from the painting process has been made by asking various producers of equipment for spray-painting and kiln-drying for information concerning energy consumption and waste percentages. Furthermore, a calculation of volatility of solvents and a calculation of the energy consumption for heating the substitution air at the ventilation has been done.

Disposal phase

The paints from TEKNOS SCHOU A/S are primarely used on Danish products of metal which are disposed to local product dealers (schredning) and from here to Staalvalsevaerket in Frederiksvaerk (remelting). Some products are also disposed with normal waste for either incineration or deposit.

The report discloses a plausible distribution in percentages of the ways of disposal in Denmark. Subject to an assessment of the quantity of paint ending up as gas emissions, incineration ash, volume waste and chemical waste, respectively, an estimation of the destiny of paints at schredning, remelting, incineration and deposit respectively, of painted metal products has been made.

In order to decide the content of carbon, nitrogen, chlorine, sulphur and heavy metals, the gas emissions have further been specified by means of analysing of the paint.

Environmental assessment of manuafacturing, use and disposal

The environmental assessment of the collected data has been made by means of a demo version of UMIPTOOL. This is an electronic tool developed in connection with the UMIP-project.

The assessment includes:

• classification of emissions according to type of environmental effect (greenhouse effect, erosion of the ozone layer, eutrophication, etc.),
• normalisation of the classified emissions compared to the Danish average figures, hereby recalculating the emissions to person equivalents
  
  and finally,
• weighting, where a factor of weight for the normalised emissions according to environmental importance is subject to a multiplication.

The assessment has been made per tonne paint and per functional unit. The functional unit has been chosen as:

"The quantity of paint needed to cover 1m² of metal plate"

which corresponds to approx. 135 g. of powdered paint, 90 g of solvent based paint and 90 g of water based paint.

The durability of the painted metal plates are not included in the functional unit, because TEKNOS SCHOU A/S has not been able to identify differences in durability of the painted metal sufaces when the mentioned thickness of paint layers are used.

The result of the environmental assessment is shown in chapter 8. For the 3 examined paints the following areas are given the highest priority:

Processes:
Reduction of the quantity of hazardous waste and the consumption of electricity in the utility phase for paints based on solvents and on water.

Substances:
Reduction/substitution of xylene in solvent based paint and TGIC-hardener in powdered paint.

Plan of action

In the project a detailed plan of action has not been made. A list of the environmental topics which are to be worked with, to solve some of the problems mentioned above, has been made. The topics are:

• focus on the raw materials, which ought to be replaced
• minimisation of environmental impact in the utility phase (reduction of the content of solvents and of substances ending up as chemical waste
• manufacturing of kiln-dried paints with a small consumption of energy
• focus on reuse of paint

Only the first subject are selected to be further elaborated in this report, i.e. replacement of hazardous raw materials.

Screening of raw materials

Due to the big number of raw materials (20 - 40 for each type of paint ), it has been necessary to select the most important from an environmental point of view. This selection is based on evaluation of:

1. a weight criterion
2. Overall materials- and energy consumption, and emission of hazardous substances to air or water in manufacturing the raw material
3. Environmental problems in manufacturing, use and disposal of the paint caused by the raw material

The screening disclosed that the essential raw materials, in an environmental point of view, were the solvent xylene, the hardener TGIC and the white pigment TiO₂.

Xylene

It is possible to substitute xylene in the solvent based paints with e.g. paraffin's or other hydrocarbons, but they are much more expensive (a factor 10) and will impose other problems with occupational health e.g. Consequently, a more realistic alternative will be to change to a total new painting system as e.g. water based paint or powdered paint, which are exactly the alternatives investigated in this report. Thus it has been decided not to do any further investigations concerning alternative solvents in this report.

TiO₂

TiO₂ is a supreme white pigment because of its refractive index and in real world experience, there are no practical alternatives. However, TiO₂ can be manufactured by two alternative process routes called the sulphate process and the chloride process which are compared in this report. Due to the very widespread use of TiO_2, there are a lot of investigations and data concerning environmental impacts through the total life cycle of this substance. Apart from general literature from handbooks, data from Buwal /8/, Tioxide /17/ og KRONOS TITAN /22/ have mostly been used in this report.

By comparing the environmental impacts during the whole life cycle of TiO₂ it has not been possible to encounter any substantial differences in the two process routes. Compared to the chloride process the sulphate process tends to cause higher impacts. However, this is hidden by variations in the emission of small amounts of e.g. mercury by both processes.

TGIC-hardener

TGIC is today widely used as hardener in manufacturing powdered paints. Unfortunately TGIC has some problematic occupational health characteristics, as e.g. allergen effects. According to EU-rules for chemicals, TGIC must be marked with the symbol T (toxic) as of May 31 1998.

Therefore, Technos Schou A/S wants to substitute TGIC with a more environmentally correct substance and the most promising candidate pt. is b -hydroxyalkylamide. These two substances are the ones investigated and compared in this report.

Environmental assessment of alternative rawmaterials

As no final LCA's have been made in advance for hardeners as it was the case for TiO₂, it has been necessary to make a detailed inventory of the manufacturing processes, chemical reactions, resource consumption and emissions for each step back to extraction of the primary raw materials.

Comparing the environmental impacts by substituting TGIC with b -hydroxyalkylamide showed both improvements and recessions:

Improvements:

• Reduction of occupational health impacts (related to TGIC as allergen and toxic substance)
• Classification of powder waste are changed from hazardous waste to common waste, under the assumption that all TGIC in powder paints are substituted with b -hydroxyalkylamid.
• Reduction of emissions of chlorine compounds by disposal of powdered paints

Recessions:

• Small increases in consumption of resources (natural gas, oil and coal)
• Small increases in greenhouse effects (caused by emission of N₂O)

Due to the possibilities to abate the emission of N₂O it is in total evaluated as an improvement to substitute TGIC with b -hydroxyalkylamide. Removal of T-marked substances are additionally a high priority subject at TEKNOS SCHOU A/S.