MAKE A STAINLESS STEEL KITCHEN BACK-SPLASH

We often get asked what type of Stainless Steel Sheet can be used as a kitchen back-splash.
Stainless Steel 304 is the recommended grade. It should have a #4 brushed finish. The finish of this grade looks very similar to the type used for stainless kitchen appliances. This material can be cut to the size that you need, and can be adhered to the wall using construction adhesive.

This material comes with one-side brushed (#4 grit finish). It will have a peelable protective plastic layer that can be removed once the item has been installed. The reverse side is a plain matte finish, which can be used as the gluing surface.

You must consider the direction that you wish the brushed direction to go, before ordering your sizes. Make sure that you provide those details to one of our stores doing the cutting (or place in the comments section if ordering online). The brushed grain can either go along your length or across your width of the piece(s) that you need. A typical instruction to the store might be: “please cut with brushed grain along the 12 inch length”.

Stainless steel sheet comes in many thicknesses, from 0.125” (1/8”) thick to 0.030” (1/32”) thick. While each project may have a particular thickness in mind, the most commonly used thicknesses are 0.030” or 0.036” Thick. Please keep in mind that the thicker material will cost and weigh more.

INSTALLING STAINLESS STEEL BACK-SPLASH

1. Make sure that the wall is flat. Remove all build up and repair any large dents.
2. Test the placement of the sheet. Make a supporting cleat if the backsplash is not being supported by the counter top.
3. Lay the sheet with the finished (#4) side down on a flat surface.
4. Apply construction adhesive to the back side (using caulking gun), making sure that the lines of adhesive go back and forth across the entire sheet.
5. Make sure that you evenly spread the adhesive on the sheet, using a putty knife.
6. Place the stainless steel sheet against the wall with either the bottom resting against the cleat or the countertop. Once in place press the sheet against the wall.
7. Using a soft cloth, move from side to side of the sheet, pressing firmly to remove any air bubbles that could be behind the sheet.
8. Once the glue has dried and the project is complete, remove the protective layer.

[ Wiki ]STAINLESS STEEL FINISHING OPTIONS

There are a number of stainless steel finishing options that alter more than just the appearance of the material. Whatever the intended use, choosing the right finish option is essential.

In projects when design is a primary consideration, an attractive finish will enhance the appeal of the end-product. For example, in architecture and the automotive industries, different finishes can be used to achieve a variety of visual effects. In retail products, particularly kitchen appliances, stainless steel No. 4 finish is one of the most popular finishes available.

The choice of surface finish is also important where fabrication processes will be applied. Rough surface finishes are appropriate when the steel will be ground prior to painting and gluing. Smooth surface finishes are better where the steel will be blended.

The choice of finish should always be clearly specified and properly defined by standard industry designations.

THE DEVELOPMENT OF THE SURFACE FINISH STANDARD

During the late 1970’s, British Steel scientists found that dull polished finishes on stainless steel showed a wide range of surface roughness. Further testing revealed that steel with high surface roughness was heavily damaged by the polishing operations, whereas steel with low surface roughness was relatively unscathed.

During the mid-1980’s dull polished finishes became widely used on projects such as high-profile architectural projects. However, it was soon discovered that some of these dull polished finishes had poor corrosion resistance, especially when exposed to seawater. Consequently a new surface finish description was introduced which remains in use to this day.

Three more common stainless steel finishing options are:

1. No. 2B – Matte finish
2. No. 4 – Brushed finish
3. No.8 – Mirror finish

NO. 2B – MATTE FINISH

No. 2B – Matte Finish

No. 2B is the mill finish, meaning it has not been processed further. Matte finishes are dull in appearance and are not ideal for atheistic end uses. However, they’re a good choice where appearance is not important or when further finishing is intended. No. 2B Matte finishes are the least expensive of the stainless steel finishing options.

The finish is produced by ‘cold rolling’ stainless steel through special rolls or dies. The cold rolling produces a smoother, less pitted surface. Next it is softened and de-scaled in acid solution. The steel is given a final pass on polished rolls to further enhance its smoothness.

Common applications include:

• Chemical plant equipment
• Pharmaceutical equipment
• Paper mill equipment
• Laundry and dry cleaning
• Refrigeration
• Sewage equipment

NO. 4 – BRUSHED FINISH

No. 4 Brushed Finish

The No. 4 Brushed finish can vary with different suppliers and even from batch to batch from the same supplier. The variations arise from differing manufacturing conditions, such as wearing of the abrasive belts used in these finishes. Some level of variation should be expected when ordering No. 4 Brushed finish. It can be helpful to request a sample of a few square inches to ensure the finish achieves the desired effect.

Brushing the stainless steel produces a distinctive look with a muted luster and a pattern of fine parallel lines. It has strong decorative appeal without being too reflective, as too much reflectiveness can be undesirable. For example, overly reflective stainless steel accents on a building could be blinding in bright sunlight. The drawbacks to this finish include reduced corrosion resistance, because the grooves of the finish are susceptible to rust.

The finish is created by sanding the stainless steel in one direction with a 120-180 grit belt, followed by softening with a 80-120 grit medium non-woven belt.

Gateway Arch

Common applications include:

• Jewelry and watches
• Home appliances
• Air conditioners
• Water heaters
• Architecture
• Automotive design

The Gateway Arch in St Louis, Missouri is the world’s tallest arch and is clad in brushed stainless steel.

The DeLorean DMC-12 sports car, most famous for being featured in the Back to the Future films, is paneled in brushed stainless steel.

NO.8 – MIRROR FINISH

Mirror finishes are highly reflective and created by polishing the stainless steel. The polishing process enhances appearance and consistency, making cleaning easier. It also masks the after-effects of welding and hides surface damage.

No. 8 Mirror finish is created by mechanically treating the surface with a series of progressively finer abrasives. Alternatively a special rolling procedure is used which can simulate the appearance of mechanical abrasion. For this stage, it is essential to remove deep scratches as any surface defects will be very noticeable on the finished product. The final process involves buffing the surface for 5-10 minutes to create a mirror-like, highly reflective finish.

A benefit of No. 8 Mirror finishing is that it improves corrosion resistance. The polishing eradicates crevices where corrosive particles can lodge themselves.

Common applications include:

• Mirrors
• Ornamental trim
• Clean rooms
• Column covers
• Wall panels
• Reflectors

[ Wiki ]Frequently Asked Questions of Stainless Steel

These are some of the questions that we frequently get asked.

What Is Stainless Steel?

Stainless steel is an alloy of Iron with a minimum of 10.5% Chromium. Chromium produces a thin layer of oxide on the surface of the steel known as the'passive layer'. This prevents any further corrosion of the surface. Increasing the amount of Chromium gives an increased resistance to corrosion.

Stainless steel also contains varying amounts of Carbon, Silicon and Manganese. Other elements such as Nickel and Molybdenum may be added to impart other useful properties such as enhanced formability and increased corrosion resistance.

When was stainless steel discovered?
There is a widely held view that stainless steel was discovered in 1913 by Sheffield metallurgist Harry Brearley. He was experimenting with different types of steel for weapons and noticed that a 13% Chromium steel had not corroded after several months. However, the picture is much more complex than this.

What is stainless steel used for?

Stainless steels of various kinds are used in thousands of applications. The following gives a flavour of the full range:

Domestic – cutlery, sinks, saucepans, washing machine drums, microwave oven liners, razor blades

Architectural/Civil Engineering – cladding, handrails, door and window fittings, street furniture, structural sections, reinforcement bar, lighting columns, lintels, masonry supports

Transport – exhaust systems, car trim/grilles, road tankers, ship containers, ships chemical tankers, refuse vehicles

Chemical/Pharmaceutical – pressure vessels, process piping.

Oil and Gas – platform accommodation, cable trays, subsea pipelines.

Medical – Surgical instruments, surgical implants, MRI scanners.

Food and Drink – Catering equipment, brewing, distilling, food processing.

Water – Water and sewage treatment, water tubing, hot water tanks.

General – springs, fasteners (bolts, nuts and washers), wire.

Does stainless steel corrode?

Although stainless steel is much more resistant to corrosion than ordinary carbon or alloy steels, in some circumstances it can corrode. It is 'stain-less' not 'stain-impossible'. In normal atmospheric or water based environments, stainless steel will not corrode as demonstrated by domestic sink units, cutlery, saucepans and work-surfaces.

In more aggressive conditions, the basic types of stainless steel may corrode and a more highly alloyed stainless steel can be used. 

What forms of corrosion can occur in stainless steels?

The most common forms of corrosion in stainless steel are:

1. Pitting corrosion - The passive layer on stainless steel can be attacked by certain chemical species. The chloride ion Cl- is the most common of these and is found in everyday materials such as salt and bleach. Pitting corrosion is avoided by making sure that stainless steel does not come into prolonged contact with harmful chemicals or by choosing a grade of steel which is more resistant to attack. The pitting corrosion resistance can be assessed using the Pitting Resistance Equivalent Number calculated from the alloy content.
2. Crevice corrosion - Stainless steel requires a supply of oxygen to make sure that the passive layer can form on the surface. In very tight crevices, it is not always possible for the oxygen to gain access to the stainless steel surface thereby causing it to be vulnerable to attack. Crevice corrosion is avoided by sealing crevices with a flexible sealant or by using a more corrosion resistant grade.
3. General corrosion - Normally, stainless steel does not corrode uniformly as do ordinary carbon and alloy steels. However, with some chemicals, notably acids, the passive layer may be attacked uniformly depending on concentration and temperature and the metal loss is distributed over the entire surface of the steel. Hydrochloric acid and sulphuric acid at some concentrations are particular aggressive towards stainless steel.
4. Stress corrosion cracking (SCC) - This is a relatively rare form of corrosion which requires a very specific combination of tensile stress, temperature and corrosive species, often the chloride ion, for it to occur. Typical applications where SCC can occur are hot water tanks and swimming pools. Another form known as sulphide stress corrosion cracking (SSCC) is associated with hydrogen sulphide in oil and gas exploration and production.
5. Intergranular corrosion - This is now quite a rare form of corrosion. If the Carbon level in the steel is too high, Chromium can combine with Carbon to form Chromium Carbide. This occurs at temperatures between about 450-850 deg C. This process is also called sensitisation and typically occurs during welding. The Chromium available to form the passive layer is effectively reduced and corrosion can occur. It is avoided by choosing a low carbon grade the so-called 'L' grades or by using a steel with Titanium or Niobium which preferentially combines with Carbon.
6. Galvanic corrosion - If two dissimilar metals are in contact with each other and with an electrolyte e.g. water or other solution, it is possible for a galvanic cell to be set up. This is rather like a battery and can accelerate corrosion of the less 'noble' metal. It can avoided by separating the metals with a non-metallic insulator such as rubber.

How many types of stainless steel are there?

Stainless steel is usually divided into 5 types:

1. Ferritic – These steels are based on Chromium with small amounts of Carbon usually less than 0.10%. These steels have a similar microstructure to carbon and low alloy steels. They are usually limited in use to relatively thin sections due to lack of toughness in welds. However, where welding is not required they offer a wide range of applications. They cannot be hardened by heat treatment. High Chromium steels with additions of Molybdenum can be used in quite aggressive conditions such as sea water. Ferritic steels are also chosen for their resistance to stress corrosion cracking. They are not as formable as austenitic stainless steels. They are magnetic.
2. Austenitic - These steels are the most common. Their microstructure is derived from the addition of Nickel, Manganese and Nitrogen. It is the same structure as occurs in ordinary steels at much higher temperatures. This structure gives these steels their characteristic combination of weldability and formability. Corrosion resistance can be enhanced by adding Chromium, Molybdenum and Nitrogen. They cannot be hardened by heat treatment but have the useful property of being able to be work hardened to high strength levels whilst retaining a useful level of ductility and toughness. Standard austenitic steels are vulnerable to stress corrosion cracking. Higher nickel austenitic steels have increased resistance to stress corrosion cracking. They are nominally non-magnetic but usually exhibit some magnetic response depending on the composition and the work hardening of the steel.
3. Martensitic - These steels are similar to ferritic steels in being based on Chromium but have higher Carbon levels up as high as 1%. This allows them to be hardened and tempered much like carbon and low-alloy steels. They are used where high strength and moderate corrosion resistance is required. They are more common in long products than in sheet and plate form. They have generally low weldability and formability. They are magnetic.
4. Duplex - These steels have a microstructure which is approximately 50% ferritic and 50% austenitic. This gives them a higher strength than either ferritic or austenitic steels. They are resistant to stress corrosion cracking. So called “lean duplex” steels are formulated to have comparable corrosion resistance to standard austenitic steels but with enhanced strength and resistance to stress corrosion cracking. “Superduplex” steels have enhanced strength and resistance to all forms of corrosion compared to standard austenitic steels. They are weldable but need care in selection of welding consumables and heat input. They have moderate formability. They are magnetic but not so much as the ferritic, martensitic and PH grades due to the 50% austenitic phase.
5. Precipitation hardening (PH) - These steels can develop very high strength by adding elements such as Copper, Niobium and Aluminium to the steel. With a suitable “aging” heat treatment, very fine particles form in the matrix of the steel which imparts strength. These steels can be machined to quite intricate shapes requiring good tolerances before the final aging treatment as there is minimal distortion from the final treatment. This is in contrast to conventional hardening and tempering in martensitic steels where distortion is more of a problem. Corrosion resistance is comparable to standard austenitic steels like 1.4301 (304). 

Is stainless steel non-magnetic?

It is commonly stated that “stainless steel is non-magnetic”. This is not strictly true and the real situation is rather more complicated. The degree of magnetic response or magnetic permeability is derived from the microstructure of the steel. A totally non-magnetic material has a relative magnetic permeability of 1. Austenitic structures are totally non-magnetic and so a 100% austenitic stainless steel would have a permeability of 1. In practice this is not achieved. There is always a small amount of ferrite and/or martensite in the steel and so permeability values are always above 1. Typical values for standard austenitic stainless steels can be in the order of 1.05 – 1.1. 

It is possible for the magnetic permeability of austenitic steels to be changed during processing. For example, cold work and welding are liable to increase the amount of martensite and ferrite respectively in the steel. A familiar example is in a stainless steel sink where the flat drainer has little magnetic response whereas the pressed bowl has a higher response due to the formation of martensite particularly in the corners.

In practical terms, austenitic stainless steels are used for “non-magnetic” applications, for example magnetic resonance imaging (MRI). In these cases, it is often necessary to agree a maximum magnetic permeability between customer and supplier. It can be as low as 1.004.

Can I use stainless steel at low temperatures?

Austenitic stainless steels are extensively used for service down to as low as liquid helium temperature (-269 deg C). This is largely due to the lack of a clearly defined transition from ductile to brittle fracture in impact toughness testing.

Toughness is measured by impacting a small sample with a swinging hammer. The distance which the hammer swings after impact is a measure of the toughness. The shorter the distance, the tougher the steel as the energy of the hammer is absorbed by the sample. Toughness is measured in Joules (J). Minimum values of toughness are specified for different applications. A value of 40 J is regarded as reasonable for most service conditions.

Steels with ferritic or martensitic structures show a sudden change from ductile (safe) to brittle (unsafe) fracture over a small temperature difference. Even the best of these steels show this behaviour at temperatures higher than -100 deg C and in many cases only just below zero.

In contrast austenitic steels only show a gradual fall in the impact toughness value and are still well above 100 J at -196 deg C. 

Another factor in affecting the choice of steel at low temperature is the ability to resist transformation from austenite to martensite.

Can I use stainless steel at high temperatures?

Various types of stainless steel are used across the whole temperature range from ambient to 1100 deg C. The choice of grade depends on several factors:

1. Maximum temperature of operation
2. Time at temperature, cyclic nature of process
3. Type of atmosphere, oxidising , reducing, sulphidising, carburising.
4. Strength requirement

In the European standards, a distinction is made between stainless steels and heat-resisting steels. However, this distinction is often blurred and it is useful to consider them as one range of steels.

Increasing amounts of Chromium and silicon impart greater oxidation resistance. Increasing amounts of Nickel impart greater carburisation resistance.

What is 'multiple certification'?

This is where a batch of steel meets more than one specification or grade. It is a way of allowing melting shops to produce stainless steel more efficiently by restricting the number of different types of steel. The chemical composition and mechanical properties of the steel can meet more than one grade within the same standard or across a number of standards. This also allows stockholders to minimise stock levels.

For example, it is common for 1.4401 and 1.4404 (316 and 316L) to be dual certified - that is the carbon content is less than 0.030%. Steel certified to both European and US standards is also common.

[ Wiki ]What surface finishes are available/application do i choose on stainless steels?

What surface finishes are available on stainless steels?

There are many different types of surface finish on stainless steel. Some of these originate from the mill but many are applied later during processing, for example polished, brushed, blasted, etched and coloured finishes.

The importance of surface finish in determining the corrosion resistance of the stainless steel surface cannot be overemphasised. A rough surface finish can effectively lower the corrosion resistance to that of a lower grade of stainless steel.

The European standards for stainless steels have attempted to define the most common surface finishes. However, due to the proprietary nature of many suppliers’ finishes, it is unlikely that complete standardisation is possible. This is a summary of the most common types for each product form

Common Surface Finishes for Flat Products from EN 10088-2 (for full list see Specifying finishes for stainless steel flat products (sheet and plate)

Surface Finish Code		Description
Mill finishes
1D		Hot rolled, heat treated, pickled. The most common hot rolled finish. A non reflective, rough surface. Not normally used for decorative applications
2B		Cold rolled, heat treated, pickled, pinch passed. The most common cold rolled mill finish. Dull grey slightly reflective finish. Can be used in this condition or frequently is the starting point for a wide range of polished finishes.
2D		Cold rolled, heat treated, pickled.
2H		Work hardened by rolling to give enhanced strength level. Various ranges of tensile or 0.2% proof strength are given in EN 10088-2 up to 1300 MPa and 1100 MPa respectively dependent on grade
2Q		Cold rolled hardened and tempered. Applies to martensitic steels which respond to this kind of heat treatment.
2R		Cold rolled and bright annealed, still commonly known as BA. A bright reflective finish. Can be used in this condition or as the starting point for polishing or other surface treatment processes e.g. colouring
	In the following codes “1” refers to hot rolled being the starting point and “2” as cold rolled
Special Finishes
1G or 2G		Ground. Relatively coarse surface. Unidirectional. Grade of polishing grit or surface roughness can be specified
1J or 2J		Brushed or dull polished. Smoother than 1G/2G. Grade of polishing grit or surface roughness can be specified
1K or 2K		Satin polish. Similar to 1J/2J but with maximum specified Ra value of 0.5 micron. Usually achieved with SiC polishing belts. Alumina belts are strongly discouraged for this finish as this will have detrimental effect on corrosion resistance. Recommended for external architectural and coastal environments where bright polish (1P/2P) is not acceptable.
1P/2P		Bright polished. Non-directional, reflective. Can specify maximum surface roughness. The best surface for corrosion resistance.
2L		Coloured by chemical process to thicken the passive layer and produce interference colours. A wide range of colours is possible.
1M/2M		Patterned. One surface flat.
1S/2S		Surface coated e.g. with tin = Terne coating
2W		Corrugated. Similar to patterned but both surfaces are affected
Bead blasting		Not in EN 10088-2. Work being undertaken to more accurately define finishes.

How do I choose which stainless steel to use?

Most decisions about which steel to use are based on a combination of the following factors:

1. What is the corrosive environment? – Atmospheric, water, concentration of particular chemicals, chloride content, presence of acid.
2. What is the temperature of operation? – High temperatures usually accelerate corrosion rates and therefore indicate a higher grade. Low temperatures will require a tough austenitic steel.
3. What strength is required? – Higher strength can be obtained from the austenitic, duplex, martensitic and PH steels. Other processes such as welding and forming often influence which of these is most suitable. For example, high strength austenitic steels produced by work hardening would not be suitable where welding was necessary as the process would soften the steel.
4. What welding will be carried out? - Austenitic steels are generally more weldable than the other types. Ferritic steels are weldable in thin sections. Duplex steels require more care than austenitic steels but are now regarded as fully weldable. Martensitic and PH grades are less weldable.
5. What degree of forming is required to make the component? – Austenitic steels are the most formable of all the types being able to undergo a high degree of deep drawing or stretch forming. Generally, ferritic steels are not as formable but can still be capable of producing quite intricate shapes. Duplex, martensitic and PH grades are not particularly formable.
6. What product form is required? – Not all grades are available in all product forms and sizes, for example sheet, bar, tube. In general, the austenitic steels are available in all product forms over a wide range of dimensions. Ferritics are more likely to be in sheet form than bar. For martensitic steels, the reverse is true.
7. What are the customer’s expectations of the performance of the material? – This is an important consideration often missed in the selection process. Particularly, what are the aesthetic requirements as compared to the structural requirements? Design life is sometimes specified but is very difficult to guarantee.
8. There may also be special requirements such as non-magnetic properties to take into account.
9. It must also be borne in mind that steel type alone is not the only factor in material selection. Surface finish is at least as important in many applications, particularly where there is a strong aesthetic component. See Importance of Surface Finish.
10. Availability. There may be a perfectly correct technical choice of material which cannot be implemented because it is not available in the time required.
11. Cost. Sometimes the correct technical option is not finally chosen on cost grounds alone. However, it is important to assess cost on the correct basis. Many stainless steel applications are shown to be advantageous on a life cycle cost basis rather than initial cost. See Life Cycle Costing.

The final choice will almost certainly be in the hands of a specialist but their task can be helped by gathering as much information about the above factors. Missing information is sometimes the difference between a successful and unsuccessful application. See also General principles for selection of stainless steels