Life Cycle Assessment (LCA) can assist in: ⎯ identifying opportunities to improve the environmental performance of products at various points in their life cycle ⎯ informing decision-makers in industry, government or non-government organizations (e.g. for the purpose of strategic planning, priority setting, product or process design or redesign), ⎯ the selection of relevant indicators of environmental performance, including measurement techniques, and ⎯ marketing (e.g. implementing an eco-labelling scheme, making an environmental claim, or producing an environmental product declaration).
There are four phases in an LCA study: a) the goal and scope definition phase: The scope, including the system boundary and level of detail, of an LCA depends on the subject and the intended use of the study. The depth and the breadth of LCA can differ considerably depending on the goal of a particular LCA. b) the inventory analysis phase: The life cycle inventory analysis phase (LCI phase) is the second phase of LCA. It is an inventory of input/output data with regard to the system being studied. It involves collection of the data necessary to meet the goals of the defined study c) the impact assessment phase: The life cycle impact assessment phase (LCIA) is the third phase of the LCA. The purpose of LCIA is to provide additional information to help assess a product system’s LCI results so as to better understand their environmental significance. d) the interpretation phase: Life cycle interpretation is the final phase of the LCA procedure, in which the results of an LCI or an LCIA, or both, are summarized and discussed as a basis for conclusions, recommendations and decision-making in accordance with the goal and scope definition.
Insist on rights of humanity and nature to co-exist in a healthy, supportive, diverse and sustainable condition.
Recognize interdependence. The elements of human design interact with and depend upon the natural world, with broad and diverse implications at every scale. Expand design considerations to recognizing even distant effects.
Respect relationships between spirit and matter. Consider all aspects of human settlement including community, dwelling, industry and trade in terms of existing and evolving connections between spiritual and material consciousness.
Accept responsibility for the consequences of design decisions upon human well-being, the viability of natural systems and their right to co-exist.
Create safe objects of long-term value. Do not burden future generations with requirements for maintenance or vigilant administration of potential danger due to the careless creation of products, processes or standards.
Eliminate the concept of waste. Evaluate and optimize the full life-cycle of products and processes, to approach the state of natural systems, in which there is no waste.
Rely on natural energy flows. Human designs should, like the living world, derive their creative forces from perpetual solar income. Incorporate this energy efficiently and safely for responsible use.
Understand the limitations of design. No human creation lasts forever and design does not solve all problems. Those who create and plan should practice humility in the face of nature. Treat nature as a model and mentor, not as an inconvenience to be evaded or controlled.
Seek constant improvement by the sharing of knowledge. Encourage direct and open communication between colleagues, patrons, manufacturers and users to link long term sustainable considerations with ethical responsibility, and re-establish the integral relationship between natural processes and human activity.
(…) plant based materials have a valuable benefit for health, ecologic, comfortable habitat (moisture management, thermic and acoustic) and sustainable materials (…) can be qualified as environmental-friendly and efficient multi-functional (…) The use of crushed hemp (shiv), flax and other plants associated to mineral binder represents the most popular solution adopted in the beginning of this revolution in building materials (…) in particular, for hemp, for which the corners of the market are as varied as fibers for the automobile industry, foodstuffs for the grain or indeed the wood of the stem for construction (…) Indeed, many projects aim to create construction materials using one or more forms of lignocellular matter as a reinforcement to the structure rather than as a lightweight aggregate with an insulating purpose (…) More recently, projects used various sources of bio-aggregates, such as wood, coconut, sisal, palm, bamboo, or bagasse (…) Bio-based aggregate are coming from the stem of plants cultivated either for their fibers (hemp, flax, etc.) or for their seeds (oleaginous flax, sunflower, etc.)
Agro-concrete: “A mix between granulates from lignocellular plant matter coming directly or indirectly from agriculture or forestry, which form the bulk of the volume, and a mineral binder”
Hempcrete is a mixture, in very changeable proportions, of two very different components: a plant-based granulate and a hydraulic and aerated setting binder. It exhibits multiphysical behaviour which is unusual in the domain of construction materials. Indeed, the particles of hemp wood are characterized by a high degree of porositywhich results in a high capacity to deform, absorb sounds and have hygrothermal transfer ability: this is one of the essential characteristics which set hempcretes apart from tradition mineral-based concretes for which the granulates are considered non-deformable (…) the variability of the behaviour depending on the formulation enables us to adjust and optimize the performances of this material for diverse applications as a roof filling material, in walling or as flagging (…) It can undergo differential compression, contraction or dilation with no apparent cracking (…) Hemp-based materials are considered as phase-change materials (PCM): the thermal behavior reduces the amplitude of the variations in the ambient air temperature, whilst improving the thermal comfort by bringing down the surface heat of the material. Thus, the use of such materials is an excellent means of passively regulating the indoor temperature, and thereby decreasing the building’s energy requirements (…) these materials are able to improve summer and winter comfort, and stabilize the indoor temperature between day and night, whilst preventing the phenomena of condensation and dampness on the walls (…) 1.8 tons of CO2 are sequestered for every ton of hemp shiv used (…) there is a favorable impact on the greenhouse effect; the hempcrete wall constitutes an interesting carbon absorber for a duration of at least 100 years (…) Some studies have shown that wetting/drying cycles, used to simulate natural variations of humidity, had an influence on the mechanical and thermal properties of hempcretes (…) fungi may also appear at the surface of materials
The theme of the 19th Oslo Architecture Triennale, Enough: The Architecture of Degrowth plays with the explosive power of this word to open up new debates into how much the pursuit of economic growth has damaged the environment and of the need to try out new solutions in architecture (floornature). The curators (Matthew Dalziel, Phineas Harper, Cecilie Sachs Olsen and Maria Smith) argue that “architects are mistaken if they believe they can confront the climate crisis by merely rethinking the way they design buildings. Instead, it is the economy and the very armature of our civilisation that requires a rigorous redesign.” (AR)
You must be brave to peel back the skin concealing the ugly ribcage of our economic system, its guts ingesting gas, coal, trees, animals, minerals, water and clean air and flatulently defecating an endless stream of clothes, plastic bags and neat packets of processed food. (AR)
The program develops in the “Academy,” the “Theatre,” and the “Playground,” until November 24. (Official site)
The base of the Wikkelhouse is ‘virgin fiber paperboard’, which is made from Scandinavian trees. This so called goldboard, is wrapped around a huge mold, with a method patented by RS Developments, while environmentally friendly glue is added. This creates a tough and insulating sandwich structure. By this wrapping process a heat insulation and construction method are integrated in a sustainable way. Afterwards each segment is finished with a protective film and a shell of wooden slats.Wikkelhouse meets the criteria for temporary or permanent housing. It is about eight times more durable than traditional construction.