Tag Archives: wood
Wood Resources International LLC: Steady Increase In Global Trade Of Wood Chips The Past Ten Years; Japan And China Imported 83 Percent Of Traded Hard
SEATTLE, Aug 20, 2013 (BUSINESS WIRE) — The global pulp industry has increased its importation of wood chips the past ten years, reaching the second highest import levels on record in 2012, reports the Wood Resource Quarterly. Japan, China, Finland and Turkey were the largest importing countries last year. Wood chips are one of the few forest products commodities that have seen a steadily increasing trend in globally traded volumes the past decade. With the exception of 2009, when global production of pulp fell by about ten percent and the demand for wood fiber was down, international trade of wood chips has increased every year from 2000 to 2011, as reported in the Wood Resource Quarterly. (www.woodprices.com) From 2009 to 2012, global chip trade increased by 6.5 million tons to just over 31 million tons, valued at over five billion US dollars, slightly below the all-time high reached in 2011. Much of the increase in chip imports has been because of the expansion of MDF production capacity in Turkey and due to major investments in pulp capacity in China. The top ranking of chip-importing countries has changed quite considerably the past five years. Although Japan is still, by far, the largest chip importer in the world, import volumes have declined from a record-high of almost 15 million tons in 2008 to just over 11 million tons in 2012. China, on the other hand, has gone from being a net exporter of chips less than ten years ago to become the second largest importer of wood chips in the world. With the expansion of pulp production capacity in China and the lack of domestic fiber sources, it is likely that China will surpass Japan as the world largest chip importer within 2-3 years. Japan and China are the two dominant consumers of globally traded chips. Their dominance is particularly accentuated for hardwood chips, where they imported 83 percent of the world’s total imports in 2012. Pulp mills in Finland, the third largest chip importer, have for a long time relied on residual chips from Russian sawmills with close proximity to the border and on chips from the Baltic States, as reported in the Wood Resource Quarterly. This trade has increased in recent years. The fourth on the import ranking list for 2012 is Turkey, which has become a major chip destination in just the past few years. It is likely that global trade of wood chips will continue to go up in the coming years for two main reasons because 1) there are limited forest resources in some of the countries which are expanding industry capacity and 2) some forest companies are making the strategic decision to diversify their supply sources and import wood chips rather than procure marginal fiber supplies locally. Global pulpwood and timber market reporting is included in the 52-page quarterly publication Wood Resource Quarterly (WRQ). The report, established in 1988 and with subscribers in over 30 countries, tracks sawlog, pulpwood, lumber and pellet prices, trade and market developments in most key regions around the world. To subscribe to the WRQ, please go to www.woodprices.com Wood Resources International LLC (WRI), an internationally recognized forest industry-consulting firm established in 1987, publishes two quarterly timber price reports and have subscribers in over 30 countries. The Wood Resource Quarterly, established in 1988, is a 52-page market report and includes sawlog prices, pulpwood and wood chip price and market commentary to developments in global timber, biomass and forest industry. The other report, the North American Wood Fiber Review, tracks prices of sawlogs, pulpwood, wood chips and biomass in most regions of Canada and the US. This information was brought to you by Cision http://news.cision.com SOURCE: Wood Resources International LLC Continue reading
Wood Waste to Biofuel Goes Commercial
Posted: 08/01/2013 VERO BEACH, FL – INEOS Bio announced that its Indian River BioEnergy Center is producing cellulosic ethanol at commercial scale. First ethanol shipments will be released in August. The $130 million, 65-employee oepration has a capacity of 8 million gallons of fuel annually, and represents the first commercial-scale production in the world using INEOS Bio’s gasification and fermentation technology for conversion of biomass waste into bioethanol and renewable power. Woodworking Network reported previously on INEOS Biofuel’s initial support from USDA biofuel development funds, and the placement of $ 75 million in venture capital backing for the wood-to-fuel venture . The BioEnergy Center is a joint venture project between INEOS Bio and New Planet Energy . The facility has already converted several types of waste biomass material into bioethanol, including vegetative and yard waste, and citrus, oak, pine, and pallet wood waste. It will have an annual output of eight million gallons (24kta) of cellulosic ethanol and six megawatts of renewable power. The Center is also permitted to utilize municipal solid waste, quantities of which will be used for bioethanol production at the Center during 2014. “Our team at Vero Beach have successfully addressed the challenges of moving a new technology to large production scale for the very first time,” said Peter Williams, CEO of INEOS Bio and Chairman of INEOS New Planet BioEnergy. “We are now pleased to announce that we are producing commercial quantities of bioethanol from vegetative and wood waste, and at the same time exporting power to the local community – a world first.” The biofuels produced in Florida will anchor the new production of cellulosic ethanol under the U.S. Renewable Fuels Standard. INEOS Bio says it is working with other companies and cities globally to use this technology as a new direction for waste disposal and the production of advanced biofuels and renewable power. – See more at: http://www.woodworki…h.cPOMtivj.dpuf Continue reading
If We Burn Wood For Energy, We Can’t Have Our Cake And Eat It
Whether more power stations should switch to burning wood or biomass is debatable. David Cheskin/PA Many countries have turned to the planet’s forests to meet their need for renewable energy, burning wood chips and pellets produced at home or abroad in power stations to generate electricity. But a report from the European Environment Agency published this week urged caution over what to burn, and how. There’s no question that if managed sustainably – which absolutely rules out turning tropical forests into palm oil plantations – wood-powered bioenergy can be an effective renewable energy source. In some cases, wood energy markets even encourage good forestry practice that can improve forest health and reduce fire and insect risks. And many experts agree that high yield, short rotation plantations of fast-growing willow or poplar make sense, depending on the land-uses these operations displace. But the question of whether wood bioenergy is problematic from a climate change perspective is much harder to answer. If we burn wood from a forest to produce heat or electricity or both, would the carbon emissions be re-sequestered as the forest re-grows? Is it accurate to consider wood biomass energy to be carbon neutral in terms of greenhouse gas emissions? Forest carbon is sequestered – soaked up from the atmosphere – by plants though photosynthesis, stored in living and dead biomass, and ultimately released back to the atmosphere in the form of carbon dioxide through plant and animal respiration and decomposition. This might suggest that the carbon locked up in forests is part of a global biogenic carbon cycle , separate and distinct from that humans have released by burning fossil fuels. It seems simple, intuitive even, but it’s not that straightforward. Even the concept of “biogenic carbon” is disputed. In our paper we contended that the concept of biogenic carbon is a red herring, because what really matters is the net amount of carbon in the atmosphere, regardless of source. Others will adamantly disagree. In many cases, poorly supported assumptions continue to underpin a sudden rush to develop wood bioenergy power generation around the world – often backed by subsidies. In my opinion, policies promoting wood bioenergy have developed quicker than the science that examines the potential tradeoffs, net effects, and consequences. Science needs time to explore the complexities of an issue like bioenergy. Only proper study can the scientific community provide more informed answers to important policy questions. The crux of the debate comes down to whether or not there will be an initial increase in greenhouse gas emissions if more wood is used for bioenergy (a carbon “debt”), particularly if it is harvested from growing trees, followed by a delay before a net emissions reduction is achieved (the “dividend”). And if so, how long that delay would be. This was structure of the argument laid out in a now infamous study conducted for the state of Massachusetts in the US. A paper by Dr Giuliana Zanchi and colleagues found immediate emissions benefits from using biomass leftover from harvests or from plantations established on marginal agricultural land, assuming biomass was substituted for coal and gas. But intensified harvesting of existing forests was projected to incur a carbon debt lasting many decades. Generating thermal energy instead of electricity has been shown to incur much shorter debt, for example. Getting this right is vital, because we have a window of only the next few decades to stabilise atmospheric greenhouse gases, beyond which some scientists believe climate disruption will be irreversible. So, assuming there will be some degree of debt in the near future and a consequent time lag before an overall net reduction of emissions, we can minimise both by following certain practises. Using by-product or waste biomass, that does not involve intensive forest harvesting , practising excellent sustainable forestry techniques, and building small-scale, highly efficient energy generation applications with minimal waste. Policies should promote high-efficiency energy applications, such as combined heat and power. Studies have found smaller bioenergy projects such as those for homes, housing estates or municipal buildings have much lower net emissions than large, industrially-sized plants. The choice of what not to use is just as important – substituting wood for coal results eliminates considerably more carbon emissions than substitution for natural gas. My research group , using data from bioenergy harvests and energy production across the northeastern United States, came to completely different conclusions depending on the baseline used as a reference to evaluate net emissions. The results swung from carbon negative to carbon positive if the baseline used was the amount of carbon that would have been sequestered had wood bioenergy not been used (with all other things being equal, and taking into account avoided emissions and direct and indirect energy uses associated with wood harvesting). Conversely, if the baseline is simply the amount of carbon currently being emitted at the present date, then most forest management schemes, including wood bioenergy, lowered cabon emissions over the long term. This was true so long as they incorporated the principles of sustainable harvest scheduling that maintain stable forest levels to stock carbon across the landscape as a whole. Should we stop investing in and promoting wood bioenergy? No – but we should proceed with caution, using the best available science. Policymakers will need to weigh the benefits and tradeoffs to minimise unintended consequences such as emissions increasing in the short-term. Go local, go small scale, go high efficiency, and develop rigorous forest harvesting standards and guidelines. When it comes to wood bioenergy, it is unlikely we will be able to have our cake and eat it too. Continue reading