- Structural Steel Detailing Manual Zinc Paint structural steel detailing manual zinc paint ebook structural steel detailing manual zinc paint currently available at wwwcomercomerco for. Such as variations in the composition/structure of. Zinc coating to fabricated iron or steel material. Org) has produced a book detailing all aspects of.
Cost effective corrosion protection of structural steelwork should present little difficulty for common applications and environments if the factors that affect durability are recognised at the outset. There are many steel structures that have continued in use satisfactorily for many years even in adverse conditions. The first major iron structure, the bridge in Coalbrookdale UK, has survived over 200 years whilst the Forth rail bridge over 100 years old is legendary. Today, modern durable protective coatings are available which, when used appropriately, allow extended maintenance intervals and improved performance.
The key to success lies in recognising the corrosivity of the environment to which the structure will be exposed and in defining clear and appropriate coating specifications. Where steel is in a dry heated interior environment the risk of corrosion is insignificant and no protective coating is necessary. Conversely, a steel structure exposed to an aggressive environment needs to be protected with a high performance treatment and may need to be designed with maintenance in mind if extended life is required. The optimum protection treatment, which combines appropriate surface preparation, suitable coating materials, required durability and minimum cost, is achievable using modern surface treatment technology. Schematic representation of the corrosion mechanism for steel The corrosion of structural steel is an electrochemical process that requires the simultaneous presence of moisture and oxygen.
In the absence of either, corrosion does not occur. Essentially, the iron in the steel is oxidised to produce rust, which occupies approximately 6 times the volume of the original material consumed in the process. The general is illustrated here. As well as general corrosion, there are various types of localised corrosion that can also occur;, and.
However, these tend not to be significant for structural steelwork. The rate at which the corrosion process progresses depends on a number of factors relating to the ‘micro-climate’ immediately surrounding the structure, principally the and the level. Because of variations in atmospheric environments, corrosion rate data cannot be generalised. However, environments can be broadly classified, and corresponding measured steel corrosion rates provide a useful indication of likely corrosion rates. More information can be found in BS EN ISO 12944-2 and BS EN ISO 9223. Atmospheric corrosivity categories and examples of typical environments (BS EN ISO 12944-2 ) Corrosivity category Low-carbon steel Thickness loss (μm) a Examples of typical environments (informative only) Exterior Interior C1 very low ≤ 1.3 - Heated buildings with clean atmospheres, e.g.
Offices, shops, schools, hotels C2 low 1.3 to 25 Atmospheres with low level of pollution: mostly rural areas Unheated buildings where condensation can occur, e.g. Depots, sports halls C3 medium 25 to 50 Urban and industrial atmospheres, moderate sulphur dioxide pollution; coastal area with low salinity Production rooms with high humidity and some air pollution, e.g. Steel beam emerging from an automatic blast cleaning unit is the essential first stage treatment of a steel substrate before the application of any coating, and is generally accepted as being the most important factor affecting the total success of a corrosion protection system. The performance of a coating is significantly influenced by its ability to adhere properly to the substrate material. The of steel can vary in terms of the amount of residual millscale and degree of initial rusting. However, generally it is an unsatisfactory base upon which to apply modern, high performance protective coatings.
A range of exist, but by far the most significant and important method used for the thorough cleaning of mill-scaled and rusted surfaces is. The standard grades of cleanliness for in accordance with ISO 8501-1 are:. Sa 1 – Light blast cleaning. Sa 2 – Thorough blast cleaning. Sa 2½ – Very thorough blast cleaning. Sa 3 – Blast cleaning to visually clean steel Manual blast cleaning (Video courtesy of Corrodere/MPI) The surface preparation process not only cleans the steel, but also introduces a suitable to receive the protective coating.
High build and need a coarse angular surface profile to provide a mechanical key. This is achieved by using grit abrasives. Shot abrasives are used for thin film such as. The difference between shot and grit abrasives and the corresponding surface profiles produced is illustrated below in the three-dimensional diagrams obtained from non-contact surface characterisation equipment.
Grit abrasive After, it is possible to examine for surface imperfections and surface alterations caused during, e.g. Certain surface imperfections introduced during the original processing of the steel may not be detrimental to the performance of a coating in service, particularly for structures in relatively low risk environment categories. However, depending upon the specific requirements of the structure, it may be necessary to carry out to remove surface imperfections on welds and cut edges as well as soluble salts to produce an acceptable surface condition for painting.
Paint coatings Main article. Cross section through a multi-coat paint system for steel structures have developed over the years to comply with industrial environmental legislation and in response to demands from bridge and structure owners for improved durability performance. A paint consists of a, dispersed in a, and dissolved in a. The most common methods for the is either by their pigmentation or by their binder type. A modern usually comprises a sequential coating application of paints or alternatively paints applied over to form a ‘duplex’ coating system. Protective paint systems usually consist of, and. Each coating ‘layer’ in any protective system has a specific function, and the different types are applied in a particular sequence of followed by in the shop, and finally the (or top coat) either in the shop or on site.
Are used on structural steelwork, immediately after blast cleaning, to maintain the reactive blast cleaned surface in a rust free condition through the fabrication process until final painting can be undertaken. These types of primers are not used before the application of.
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The method of and the have a significant effect on the quality and durability of the coating. Standard methods used to apply paints to structural steelwork include application by, conventional and /electrostatic airless spray. Has become the most commonly used method of applying paint coatings to structural steelwork under controlled shop conditions. And application are more commonly used for site application, though spraying methods are also used. Applied to edges and sharp corners are usually applied. The principal are temperature, both steel and ambient and humidity. These can be more easily controlled under shop conditions than on site.
With modern high performance coatings, correct application has become increasingly important to achieve the intended performance. Industry has recognised this and established a training and certification scheme for paint applicators ( – Industrial Coating Applicator Training Scheme). Registration (or to an equivalent scheme, e.g. ) has subsequently become a mandatory requirement for work on Highways England bridges and Network Rail structures. Airless paint spraying (Video courtesy of Corrodere/MPI) Metallic coatings Main article: There are four commonly used methods of applying metal coating to steel surfaces. These are, electroplating and sherardizing.
The latter two processes are not used for structural steelwork but are used for fittings, fasteners and other small items. In general the corrosion protection afforded by is largely dependent upon the choice of coating metal and its thickness and is not greatly influenced by the method of application. Hot-dip galvanizing. Steel elements being withdrawn from a typical hot-dip galvanizing bath is a process that involves immersing the steel component to be coated in a bath of molten zinc (at about 450°C) after pickling and fluxing, and then withdrawing it.
The immersed surfaces are uniformly coated with zinc alloy and zinc layers that form a metallurgical bond with the substrate. The resulting coating is durable, tough, abrasion resistant, and provides cathodic (sacrificial) protection to any small damaged areas where the steel substrate is exposed. The typical minimum average coating thickness for structural steelwork is 85μm. Cross-section through a thermally sprayed aluminium coating of zinc, aluminium, and zinc-aluminium alloys can provide long-term corrosion protection to steel structures exposed to aggressive environments. The metal, in powder or wire form, is fed through a special spray gun containing a heat source, which can be either an oxygas flame or an electric arc. Molten globules of the metal are blown by a compressed air jet onto the previously grit blast cleaned steel surface. No alloying occurs and the coating consists of overlapping platelets of metal and is porous.
The pores are subsequently sealed by applying a thin organic coating, which penetrates into the surface. It is essential that the sealer completely satisfies the filling of all porosity in the metal coating. The adhesion of sprayed metal coatings to steel surfaces is considered to be essentially mechanical in nature. It is therefore necessary to apply the coating to a clean roughened surface and with coarse grit abrasive is normally specified. Arc spraying (Video courtesy of Metallisation) Appropriate specifications Main article: The overall success of a protective coating scheme starts with a well-prepared specification. It is an essential document that is intended to provide clear and precise instructions to the contractor on what is to be done and how it is to be done. The specification should be drafted by someone with appropriate technical expertise, and it should be clear as to what is required, and what is practical and achievable.
It should be written in a logical sequence, starting with, going through each paint or metal coat to be applied and finally dealing with specific areas, e.g. It should also be as brief as possible, consistent with providing all the necessary information. The most important items of a specification are as follows:.
Metal dressing to remove sharp edges, projections etc. And steel contamination. The method of and the standard required. The maximum interval between and subsequent priming or metal coating. The types of or to be used, supported by relevant standards.
The method/s of application to be used. The number of coats to be applied and the interval between coats.
The for each coat. Where each coat is to be applied (i.e.
Shops or site) and the that are required, in terms of temperature, humidity, etc. Details for, and etc. Rectification procedures for damage, etc. The majority of steel bridges are protected according to the requirements of the, and standard specifications. Alternative coating systems and methods may be specified for other bridges but the same standards and principles of good coating practices should similarly be applied.
Inspection and quality control Main article. Range of testing and inspection instruments Inspection forms an integral part of. Its purpose is to check that the requirements of the are being complied with and to provide a report with proper records to the client. One of the greatest assets to the coating inspector is a clear written specification that can be referred to without doubt. The appointment of an appropriately qualified third party inspector should be seen as an investment in quality and not just an additional cost. Inspection of the processes, procedures and materials required for the protective coating of steel structures is vital, since a major error in even one operation cannot be easily detected after the next operation has been carried out, and if not rectified immediately can significantly reduce the expected life to first maintenance.
References. ↑ BS EN ISO 12944-2: 2017, Paints and varnishes – Corrosion protection of steel structures by protective paint systems – Part 2: Classification of environments, BSI.
↑ BS EN ISO 9223: 2012, Corrosion of metals and alloys – Corrosivity of atmospheres – Classification, determination and estimation BSI. BS EN ISO 12944-3: 2017, Paints and varnishes – Corrosion protection of steel structures by protective paint systems – Part 3: Design considerations, BSI. BS EN ISO 8501-1: 2007, Preparation of steel substrates before application of paints and related products.
Visual assessment of surface cleanliness. Rust grades and preparation grades of uncoated steel substrates and of substrates after overall removal of previous coatings, ISO Resources. Chapter 12 – Corrosion Protection Further reading. D.Deacon & R.Hudson (2012), Steel Designer’s Manual (7th Edition), Chapter 36 - Corrosion and corrosion prevention, The Steel Construction Institute.
Bayliss & D.H.Deacon (2002), Steelwork Corrosion Control (2nd edition), Spon Press See also. External links. CPD.