Showing posts with label RoHS. Show all posts
Showing posts with label RoHS. Show all posts

Tuesday, October 13, 2009

At last – the China RoHS 'catalog'!

This information was sent to me by Farnell's Gary Nevison!

Some two years late the Ministry of Industry and Information Technology has just released the proposed first batch Key Administrative Catalogue for the Pollution Control of Electronic Information Products.

While Phase 1 which covered labelling and information was implemented in March 2007, the Phase 2 restriction requirements have slipped on several occasions.

Issued on 9 October, there will now be a one month consultation period.

The law goes into effect 10 months after the catalogue is promulgated.

Items covered include various types of phones and a wide range of printers. Some exemptions will be allowed.

Testing will be required as widely documented.

A more comprehensive report will follow.

Tuesday, September 15, 2009

Legislative update – Sept. 2009 -- REACH, RoHS2

Guest post by Gary Nevison, Farnell

Summary
The legal obligations within the REACH Regulations and the potential impact of the so called “RoHS2” proposals dominate the legislative scene at present. Also, obligations are starting to filter through as part of the eco design/energy using Products Directive that monitors energy efficiency throughout a products life cycle. Going-forward, the scope of this directive will become more diverse to encompass energy related products.

Industry, and the design engineer, needs to be aware of developments and the potential impact on their companies.

REACH
Regulation 1907/2006, the Regulation, Evaluation, Authorisation -and restriction-of Chemicals (REACH) entered into force on 1 June 2007 after almost 8 years of debate and covering some 849 pages of regulation.

The only census on chemicals, taken in 1981, highlighted that 100,106 substances were placed on the market. Of those used, manufactured or imported at levels of 1000 tonnes or more, 21 percent had no safety data at all while a further 65 percent provided insufficient safe use data. Only 3 percent had been fully tested.

At the same time, instances of allergies, asthma, certain types of cancer and reproductive disorders were on the increase in Europe. Skin diseases alone resulted in the loss of 3 million working days per year.

Driven by the obligatory flow of safety data throughout the supply chain, REACH seeks to provide protection to health and the environment.

The biggest challenge to industry to date has been around the collection of data advising where a so called Substance of Very High Concern (SVHC) is present in a product, known as an article in the regulations, at a level of 0.1% by weight of the total article.

As a minimum obligation the name of the substance along with supporting safe use data must flow downstream through the supply chain.

Substances that are categorised as SVHC include those that are carcinogenic, mutagenic or toxic for reproduction. Also, substances that are persistent, liable to bio-accumulate and toxic, and finally “others” such as endocrine disrupters that can have a particular impact on aquatic life.

Back in October 2008, the first batch of 15 substances of very high concern was published by the European Chemicals Agency and, the following January, seven of these were earmarked for a consultation on whether or not they should be subject to a very costly “authorisation of use” requirement. These seven were approved and the European Commission will determine the date when these will be added to Annex XIV.

These obligations will then enter into force some 42-48 months later on what is known as the sunset date. Where such an authorisation is approved, downstream users can only use these substances for the use that they have been authorised for and they can only be purchased from the company granted the authorisation.

The REACH data collection has resulted in the circulation of hundreds of “standard letters” in a multitude of formats. Many manufacturers have refused to reply to the ad-hoc requests they receive preferring to promote websites or central databases (these have been slow to develop).

Guidance on the regulation encourages a more pro-active approach rather than simply providing a link to a website. Likewise, there have been many random requests for information that is not obligatory such as pre-registration details and RoHS style certificates of compliance.

Future batches of SVHCs will be published on an on-going basis, with the next expected early 2010, so REACH will not be a box that can be ticked as complete for several years to come.

“RoHS2”
Looking back the Restriction of Hazardous Substances (RoHS) Directive 2002/95 entered into force on 1 July 2006. It featured six restricted substances across eight broad categories of product pulled from the 10 categories in the Waste Electrical and Electronic Equipment (WEEE) Directive. There were 29 exemptions to assist manufacturers and design engineers where no viable alternative was available and a whole raft of “grey” definitions that required clarity.

“RoHS2” proposals look to move the directive forward and provide greater clarity. However, some of its provisions will potentially have cost and resource issues for industry.

The proposals recommend that the two remaining categories from the original WEEE categories, namely medical devices and monitoring and control instruments be added to the scope from 2014 (in-vitro diagnostics from 2016 and industrial “test” equipment in 2017). These were originally omitted from the directive due to reliability concerns over the use of lead-free solder.

While there are no substances actually restricted under the proposals, four are recommended for priority assessment. Three plasticisers used in a variety of applications and a flame retardant may well be restricted. Ironically, the substances, BBP, DBP, DEHP and HBCDD are four of the seven subject to authorisation of use under the REACH Regulations.

The fate of these substances under RoHS will be open to consultation after the revised directive comes into scope sometime in 2011-2012. Either way, any restriction under RoHS will probably be sooner than under the REACH process and the analysis is unlikely to be done twice.

Under a separate review by European Commission consultants, 29 exemptions will continue under the proposals, many with amended wording for clarity, 6 will be withdrawn and one new one will be granted. These could come into force next year and that will be followed by a transposition period of, on average, 18 months allowing manufacturers the time to comply.

In addition, a further six exemptions were added in June 2009 that had been proposed a year earlier.

RoHS2 also clarifies definitions such as equipment within out of scope equipment, spare parts and military where the latter clearly does not include dual use equipment.

A standard, and rigid declaration of conformity appears in annex 7 and will replace the multitude of different certificates, statements and compliance documents under the original legislation.

There now appears to be no scope for qualifying statements such as “so far as we are aware” and “to the best of our knowledge”.

It is proposed that RoHS will become a CE mark directive placing responsibilities on manufacturers, importers and distributors. There are many requirements including building technical files and keeping for 10 years, ensuring products comply, that they are supplied with the CE mark and the manufacturer or importer is identified on the product. Sample testing should also be carried out where appropriate, and corrective action is undertaken where product is found to be non compliant.

Finally under the proposals, the broad product categories and list of indicative products move from the WEEE Directive and sit in annex 1 and 2 of the RoHS Directive.

The terminology “RoHS2” is unofficial and is used simply to highlight the proposed changes to the original directive.

Energy using Products
Directive 2005/32/EC, Energy using Products, entered into force on 11 August 2007.

The main aim is to monitor energy efficiency throughout the life cycle of a product from the mining of raw material right through to recycling at end-of-life.

The focus is clearly on the design phase of the product since it is considered that this is the determining stage affecting the resources used in a product.

The directive does not apply to means of transport (planes, cars etc) but, apart from this, the scope is deliberately broad covering, in principle, any product which when in use depends on, generates, transfers or measures energy (electricity, fossil fuel or renewable).

Obligations on manufacturers will result from a series of specific “implementing measures” the first of which was adopted in January 2009.

The criteria required before a product can be considered for assessment is that is that it must sell more than 200,000 units per year in the European Union, have a significant environmental impact and present considerable potential for improvement. The latter is important as the target is for a 20% improvement in energy efficiency by 2020.

During phase one, studies were commission on 20 broad product categories ranging from water heaters, televisions and lighting, through to imaging equipment and personal computers.

Beyond that, a further 17 categories have been highlighted from ovens and hobs, machine tools and air-conditioning equipment through to transformers and networking equipment.

Among the first obligations to come in to force were energy efficiency improvements covering standby and off-mode losses, simple converter boxes for digital television, external power supplies and office, street and domestic lighting.

However, the European Parliament has now adopted the European Commission’s (EC) proposal to widen the scope of the directive to include energy related products. Until now the Energy using Products Directive was limited to products that consume energy during use such as boilers, computers, televisions, industrial fans and light bulbs.

However, many products have an indirect impact on the energy in use such as water using devices, taps and showerheads for example, and double glazing windows or insulating material.

Improvement in design could clearly result in the significant saving of energy.

For example, water saving taps and shower heads reduce water consumption and therefore the amount of energy used for hot water.

Under the EuP Directive studies had to set requirements for individual products where, in fact, it is the performance of the whole system that often needs to be optimised not just a single component or products.

The new directive will repeal the existing 2005/32/EC.

Saturday, September 5, 2009

What's the impact of legislation on LEDs?

There is a lot of interest in Europe around the impact of legislation on LEDs. Here's a guest post by Gary Nevison, Head of Legislation, Farnell, A trading division of Premier Farnell UK Ltd.

LEDs background
Light emitting diodes or LEDs are increasingly used for lighting applications and in displays. This trend is due to research into brighter and more energy efficient devices that are able to compete with fluorescent lamps that contain small amounts of mercury.

LED lighting is often used in homes, offices and also in vehicles. Several computer manufacturers now offer laptops with LED displays instead of the standard liquid crystal displays (LCDs). A few LED televisions have also been launched recently.

LED displays are more energy efficient than LCDs in laptop PCs because they do not require the conversion of the standard laptop battery voltages to the high voltages required by LCD backlights. LED lighting is still not as energy efficient as fluorescent lighting but researchers expect to be able to attain higher efficiency in the near future.

The development of LED lighting will affect EU legislation in the future in a variety of ways:

RoHS directive
The RoHS directive has three exemptions for mercury in fluorescent lighting: One for compact fluorescent lamps, one for linear lamps and one for special lamps that are used as LCD backlights.

These exemptions are justified because LED lighting is not yet as energy efficient as fluorescent lighting and the availability of LED displays is very limited at present.

RoHS bans mercury because it is very toxic but infrared and red LEDs contain very small amounts of arsenic which is also very toxic and is a carcinogen. Green and yellow LEDs contain phosphides which are also hazardous substances.

The quantities of arsenic or phosphide used are however very much smaller than the amount of mercury in equivalent light output fluorescent lighting. Another issue is that LED lamp production is an energy intensive process that uses very toxic chemicals and so, ideally, a full life cycle assessment of LED lighting compared with fluorescent lighting should be carried out before changes are made to legislation.

It is clear however that in the future, all three of these RoHS exemptions could be repealed when viable mercury-free alternatives are available.

Energy using Products (EuP) directive
The EuP Directive aims to reduce the amount of energy used by electrical equipment and two EU regulations have been adopted that will restrict the supply of less energy efficient lamps.

Tighter restrictions will be imposed at specific dates in the future (1, 3 and 8 years after entry into force) and LEDs will inevitably be one of the alternative options available, especially when their energy efficiency improves.

REACH regulations
REACH imposes a variety of obligations on manufacturers of electrical equipment, particularly on the use of hazardous substances. Some LEDs contain arsenic and this is likely to be classified as a substance of very high concern (SVHC) and included in the Candidate List. Authorisation may also be a requirement for use of arsenic chemicals in the EU and restrictions are also possible, but unlikely.

Thursday, August 13, 2009

Is US RoHS the same as EU RoHS?

This is a guest post by Gary Nevison, Head of Legislation, Farnell, A trading division of Premier Farnell UK Ltd.

Firstly, as this new legislation is clearly not “RoHS”, it would be misleading to talk about the US RoHS compliance.

The proposed HR2420 is very different to EU RoHS and although it is claimed to be legislation designed to control hazardous substances, its main aim appears to be preventing US States imposing substance restrictions on product within scope of this legislation. It would introduce some very limited restrictions but the exemptions list is so comprehensive that these would be very few.

So, is this to be the US RoHS that we have been waiting for?

Initially, this might appear to be so, however closer scrutiny of the scope and structure of HR2420 reveals that it is better understood as an effort to limit uncoordinated piecemeal legislation on this issue by individual states.

At present, there is no federal US equivalent to EU RoHS although some states have introduced limited RoHS-like laws.

Many manufacturers would welcome a single, uniform US RoHS law as this would remove the need to meet multiple, changing requirements across US states although others, who predominantly sell internally, may be concerned about this extra restriction.

The main implications of HR2420 are for new chemicals, or major new uses of existing ones, for example products containing substances that are not included in the Toxic Substances Control Act register require certification before they can be imported.

TSCA currently imposes very few restrictions on substances, but it does affect lead-based paints, asbestos and polychlorinated biphenyls.

While the Bill proposes to restrict the same six substances as EU RoHS at the same concentration values in homogeneous materials, there are no apparent equivalents to 17 EU RoHS exemptions, and there is no use of the EU RoHS product categories.

The product scope appears quite different to EU RoHS as it seems to exclude household or consumer products and include products not covered by EU RoHS like electricity distribution equipment.

Another significant difference is that EU RoHS excludes products designed for use with voltages above 1000V AC or 1500V DC, whereas HR2420 has a limit of 300V.

The restrictions would apply to products in scope manufactured after 1 July 2010.

In summary, the scope of the Bill is quite limited, is clearly different to the EU RoHS, and mainly consists of a detailed list of exclusions and exemptions.

As the scope includes many items currently excluded from EU RoHS, the HR2420 does not appear to be a federal RoHS Bill, but more of an attempt to avoid disjointed RoHS requirements emerging for products currently outside, or on the fringe of the scope of EU RoHS.

Sunday, June 21, 2009

Alternatives for RoHS restricted substances

This is a guest post by Gary Nevison, Head of Legislation, Farnell, A trading division of Premier Farnell UK Ltd.

Substitution of HBCDD, DEHP, BBP and DBP

Background
UK: Hexabromocyclododecane (HBCDD), Bis-ethylhexyl phthalate (DEHP), Butyl benzyl phthalate (BBP) and Dibutyl phthalate (DBP) are classified by the REACH regulations as Substances of Very High Concern (SVHCs) and are included in the “Candidate List”. They have also been proposed for inclusion in Annex XIV, substances requiring authorisation for use.

The European Commission (EC) has submitted proposals to amend the RoHS Directive (so called RoHS2) and one proposal is to consider adding these four substances to the list of restricted substances. The three phthalates are also banned in children’s products in the European Union (EU) and in the USA.

This article describes their main uses and possible alternatives.

Main uses
Table 1: Main uses of the substancesSource: Farnell

Alternatives to HBCDD

HIPS
Two options are available; use a different brominated flame retardant or a different type of plastic. For example, decabromodiphenylethanol and ethylene bis-tetrabromophthalaimide are used as flame retardants in HIPS and can achieve UL94V0 and neither are restricted.

There are however no non-brominated flame retardants that can achieve UL94V0 in HIPS although there are several phosphorous-based flame retardants that can achieve UL94V0 in PC/ABS and PPE/HIPS blends which are often used for enclosures. However, some phosphorous flame retardants have certain hazardous properties and many are not fully tested.

Textiles
Several options are available including decabromodiphenyl ether (decaBDE) which is banned by RoHS but not in vehicles and some other applications. Chlorinated paraffins are also used but are toxic and aluminium polyphosphate which is the least hazardous option.

EPS
No alternatives exist that provide adequate flame retardancy but alternative insulation materials may be suitable. These include phenolic foams (highly persistent), polyurethane foams (very toxic fumes if burnt) and glass and mineral fibres.

XPS
No substitute flame retardants are available as all would need too high a loading and therefore the required properties of the XPS would not be met. Hence, different materials are the only alternative; starch based packaging chips and bubble wrap are two options.

Alternatives to DEHP, BBP and DBP
There are many alternatives, but most are not hazard-free and their properties differ. The following lists some of the more commonly used examples but many others are also used:

Table 2: Examples of alternatives plasticisersSource: Farnell

There are many others available including other phthalates, esters, phosphates, etc.

Conclusions
Hexabromocyclododecane, Bis-ethylhexyl phthalate, Butyl benzyl phthalate and Dibutyl phthalate are clearly hazardous chemicals so their use will, in the future, become increasingly restricted. There are many possible alternatives but choosing the best option is not straightforward. For each application, substitution will often give products with different properties and performance, which need to be assessed.

One of the main problems with choosing a substitute is to identify one that is safe to use and will not be restricted in the future. Di-isobutyl phthalate is the most common replacement for DBP but Germany has indicated that it intends to submit a proposal for di-isobutyl phthalate to be classified as a SVHC.

Most of the potential substitutes have not been extensively tested and in many cases test results are inconclusive or incomplete. However the test data that does exist for many of the possible alternatives indicates that they are safer options and many are increasingly used in preparations and in finished products.