Richard Levine (architect)

Last updated
Richard Levine
Born (1939-09-11) September 11, 1939 (age 84)
New York City, New York, U.S.
NationalityAmerican
Alma mater Rhode Island School of Design, Rensselaer Polytechnic Institute
Known for Raven Run Solar House
Hooker Building
Sustainable Area Budget
Scientific career
Fields Architect, Professor, Sustainability Pioneer
InstitutionsCenter for Sustainable Cities,

http://www.centerforsustainablecities.com CSC Design Studio,

Contents

http://www.cscdesignstudio.com
Website

Richard Steven "Dick" Levine (born September 11, 1939) is an American environmental architect, solar energy and sustainability pioneer, and professor at the University of Kentucky. He is one of the early solar energy innovators in the U.S., a holder of U.S. patents on structural systems and solar energy applications, and the architect of a number of award winning solar buildings including his widely published Raven Run Solar House (1974). Levine is co-director of the Center for Sustainable Cities at the University of Kentucky. His contributions to sustainable urban planning are in both the theory and practice of the sustainable city-region. He has over 150 publications on solar energy and sustainability research, conducted in Italy, Austria, China and the Middle East.

Biography

Richard Levine was born in Queens, New York. He attended Forest Hills High School. After spending a year in the chemical engineering program at the University of Rhode Island, Levine enrolled at the Rhode Island School of Design to study his true passion, Architecture. While a student at RISD, Levine invented the Coupled Pan Space Frame structural system, for which he later received a United States Patent. Levine holds a B.S.Arch from Rhode Island School of Design (RISD)(1962), [1] and an M. Arch from Rensselaer Polytechnic Institute (1963).

Levine currently divides his life between international urban sustainability research projects through The Center for Sustainable Cities, its European Union partner institutions, and private architectural practice as principal of the CSC Design Studio.

The Solar Energy Movement

Levine has been a national and international advocate for solar architectural design, and was the Founding Chair of the Sustainability Division of the American Solar Energy Society (ASES). Levine's Raven Run Solar House (1974) was the first to combine passive solar building design and active solar systems with earth tubes, an attached greenhouse, super insulation, "sundows," and a patented air collection system. Recognized as being ahead of its time, the house continues to be published today. [2] [3] [4] [5] [6] [7] His Hooker Office Building (1978) with its double glass walls with insulated aluminum louvers between them, has become the prototype for numerous energy conserving commercial buildings in Europe. [8] [9]

Sustainability

Levine's academic work is notable in that he is concerned with the ways in which the form and process of architectural design can produce operational sustainability. [10] [11] [12] This scale of analysis is unusual for an architect, and even for an urban planner. [13] Levine's work has since encompassed the multi-scale nature of sustainability.

Center for Sustainable Cities

The Center for Sustainable Cities is an interdisciplinary academic and design think-tank co-founded by Richard Levine and Ernie Yanarella, a professor of Political Science at the University of Kentucky. The Center is housed in the College of Design. The Center supports research and projects both locally and internationally, developing both the theory and practice of the sustainable city-region. The Center for Sustainable Cities is closely associated with a partner European institution- Oikodrom: the Vienna Institute for Urban Sustainability, in Austria. [14]

Operational Sustainability

In developing the Operational Definition of Sustainability, Levine and his colleagues recognized the need for approaches to ecological balance that embrace local needs and work within the needs and signals of culture and natural resources, requiring feedback at a quantifiable and appropriate scale. It is among the earlier operational definitions of sustainability. [15]

Sustainability is a concept that has many definitions, the United Nations definition of sustainability is the most widely used. It defines sustainable development as: "development which meets the needs of the present without compromising the ability of future generations to meet their own needs". [16] Because sustainability is expected to achieve many things, the UN definition is not universally-accepted and has undergone various interpretations. [17] [18] [19] [20] [21] Sustainability has been called an essentially contested concept. What sustainability is, what its goals should be, and how these goals are to be achieved, is open to interpretation and manipulation. [22] As a result, international policy in sustainability has largely come to be a reactionary means by which unsustainability is mitigated. [23]

The Operational Definition of Sustainability is a guideline for a proactive approach to negotiating ecological, cultural, and civic balance, while providing for concrete measures of accountability that preclude a simple "greening" approach. Through years of interdisciplinary collaboration between ecologists, social scientists, and urban planners, the Center for Sustainable Cities has developed the only interdisciplinary operational definition of sustainability:

Sustainability is a local, informed, participatory, balance-seeking process, operating within its Sustainable Area Budget, exporting no harmful imbalances beyond its territory or into the future, in so doing opens spaces of opportunity and possibility.
–Levine, Dumreicher, Yanarella [24]

This definition has been recognized as a concrete basis for local sustainable development by negotiating resources within a Sustainable Area Budget (SAB)(see below), using the Sustainable City-As-A-Hill (see below) as its urban form. The Operational Definition provides a strong basis for both theoretical and operational integration with the emerging fields of: Ecological Economics, Industrial Ecology, Sustainability science, Stakeholder Analysis, Material Flow Analysis, Environmental Justice, Life Cycle Analysis, Complexity Science, Biomimicry, Social policy, Public Policy, Systems modeling, Ecology, and Ecological Design. [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37]

Aalborg Charter

Richard Levine was the principal author of the Aalborg Charter, ratified at the First European Conference on Sustainable Cities and Towns, which took place in Aalborg, Denmark in 1994. <https://web.archive.org/web/20130613030243/http://ec.europa.eu/environment/urban/pdf/aalborg_charter.pdf>. The charter is part of the United Nations Agenda 21 framework for the delivery of local sustainable development put forward in the United Nations Conference on Environment and Development (Earth Summit), held in Rio de Janeiro on June 14, 1992. [38] The program calls on local authorities to engage in Local Agenda 21 processes that take a holistic view of the sustainability process. [39]

Sustainable Area Budget

Levine's main contribution has been to unite the fields of sustainability, urban design, and sustainable development with a scale-based proposal integrating urban form with computational rigor. The Sustainable Area Budget (SAB) is a land-based aggregate from which a city-region can draw its resources and negotiate those resources on a regenerative basis. [15] The SAB is similar to the Ecological Footprint approach to computational sustainability, which allows an individual to calculate the impact of personal consumer decisions on the natural environment. Footprint approaches only provide information as to how an individual can decrease negative ecological effects. [40]

The SAB, in contrast, is an operational tool for negotiating balance. It offers far greater flexibility and political leverage than footprint approaches alone. This is because the SAB negotiates resources at the scale of the city-region according to its population, not at the scale of personal action from a pre-defined set of choices. [30] [41] [42] Integral to the SAB theory is a formal relationship between an agricultural countryside and a dense urbanistic human-scale city. [43]

The Sustainable City-As-A-Hill


The Sustainable City As A Hill has been in development since the early 1980s. [44] [45] [46] [47] [48] It is a comprehensive sustainable urban framework, an operational alternative to inherently unsustainable modern patterns of city construction and development. It is an urban model that achieves integrative design at an appropriate building scale and allows for the negotiation of sustainability within the boundaries of an appropriate regional scale (using the SAB). [49] [50] The City-As-A-Hill preserves the civic character, and pedestrian scale of a traditional village, with all of the civic, residential, and commercial activities taking place on the outer surface of the city.

Inspired by the formal elements of medieval Italian Hilltowns, Levine developed a family of urban forms that respond to the human-scale social requirements of a city. Medieval Italian cities were cities upon a hill. Their metropolitan boundaries were walled off for defensive purposes, leading to an evolving language of dense urban forms and clear contextual restrictions on the limits of urban development. Levine's City-As-A-Hill takes the medieval model and carves out the interior, building a three-dimensional structure of usable commercial and industrial space within a dense pedestrian city. This city is metabolically tied to a surrounding hinterland of agricultural and ecological resources. The management of these resources is negotiated within the Sustainable-Area-Budget, according to the aggregated fair earth share of its citizens. [51] The City-As-A-Hill has been modeled in a number of contexts: in Korea, Austria, and the Appalachian region of Kentucky.

Sustainability-Driven Architecture

Levine is the principal architect at the Center for Sustainable Cities Design Studio (CSC Design Studio), a full-service architectural and urban design firm that specializes in zero-energy building projects for public and private clients. [52] When designing at the building-scale, Levine's firm is one of a few architectural practices in the United States to employ the European Passive House Standard, which is the most rigorous energy standard for building design in the world. [53] [54] [55]
Levine has referred to his architectural work as "sustainability-driven," recognizing that the scale of the single building is inadequate to comprehensively address sustainability. [56] Nevertheless, buildings account for an average of 48% of energy consumption, more than any other sector. [57] This renders energy & carbon neutrality in architecture a powerful point of leverage for energy independence, environmental protection, and economic advantage.
Levine's work is notably antithetical to the typical response to addressing sustainability within the field of architecture. This approach calls for "greening" of existing building designs, pursuing individual cost-effective tweaks, or checklists of actions, within the conventions of an outdated and inefficient building industry. [58] Levine's approach has consistently been to avoid "picking the low-hanging fruit," (e.g. changing light bulbs & installing more efficient windows) in favor of considering the building as a whole system (e.g. constructing a super-efficient building envelope & providing for natural daylighting and the use of passive solar). Because of this integrated design system, Levine's designs require 90% less energy for climate control, and 75% less for electricity. When buildings are designed from such an efficient standard, remaining energy needs can be obtained by an affordable photovoltaic electricity generating array. [59]

The CSC Design Studio headquarters is itself a zero-net-energy building, with annual electricity consumption offset by a 5.25 Kw Photovoltaic array installed in 2009. [59]

Patents

Coupled Pan Space Frame [60] (CPSF):

Super-efficient multi-stage solar air collection system:

Interview with Richard Levine

Ahmad Zohadi has created a series of questions in the form of interview in relation to design and sustainability. A number of international practitioners, academics and thinkers have been selected and invited to participate and share their views. One of them is Richard Levine. [61]

Related Research Articles

<span class="mw-page-title-main">Ecovillage</span> Community with the goal of becoming more sustainable

An ecovillage is a traditional or intentional community with the goal of becoming more socially, culturally, economically, and/or ecologically sustainable. An ecovillage strives to produce the least possible negative impact on the natural environment through intentional physical design and resident behavior choices. It is consciously designed through locally owned, participatory processes to regenerate and restore its social and natural environments. Most range from a population of 50 to 250 individuals, although some are smaller, and traditional ecovillages are often much larger. Larger ecovillages often exist as networks of smaller sub-communities. Some ecovillages have grown through like-minded individuals, families, or other small groups—who are not members, at least at the outset—settling on the ecovillage's periphery and participating de facto in the community. There are currently more than 10,000 ecovillages around the world.

Environmental design is the process of addressing surrounding environmental parameters when devising plans, programs, policies, buildings, or products. It seeks to create spaces that will enhance the natural, social, cultural and physical environment of particular areas. Classical prudent design may have always considered environmental factors; however, the environmental movement beginning in the 1940s has made the concept more explicit.

Ken Yeang is an architect, ecologist, planner and author from Malaysia, best known for his ecological architecture and ecomasterplans that have a distinctive green aesthetic. He pioneered an ecology-based architecture, working on the theory and practice of sustainable design. The Guardian newspaper (2008) named him "one of the 50 people who could save the planet". Yeang's headquarters is in Kuala Lumpur (Malaysia) as Hamzah & Yeang, with offices in London (UK) as Llewelyn Davies Ken Yeang Ltd. and Beijing (China) as North Hamzah Yeang Architectural and Engineering Company.

<span class="mw-page-title-main">Sustainable architecture</span> Architecture designed to minimize environmental impact

Sustainable architecture is architecture that seeks to minimize the negative environmental impact of buildings through improved efficiency and moderation in the use of materials, energy, development space and the ecosystem at large. Sustainable architecture uses a conscious approach to energy and ecological conservation in the design of the built environment.

An eco-city or ecocity is "a human settlement modeled on the self-sustaining resilient structure and function of natural ecosystems", as defined by Ecocity Builders. Simply put, an eco-city is an ecologically healthy city. The World Bank defines eco-cities as "cities that enhance the well-being of citizens and society through integrated urban planning and management that harness the benefits of ecological systems and protect and nurture these assets for future generations". Although there is no universally accepted definition of an 'eco-city', among available definitions, there is some consensus on the basic features of an eco-city.

<span class="mw-page-title-main">Zero-energy building</span> Energy efficiency standard for buildings

A Zero-Energy Building (ZEB), also known as a Net Zero-Energy (NZE) building, is a building with net zero energy consumption, meaning the total amount of energy used by the building on an annual basis is equal to the amount of renewable energy created on the site or in other definitions by renewable energy sources offsite, using technology such as heat pumps, high efficiency windows and insulation, and solar panels.

<span class="mw-page-title-main">Sustainable city</span> City designed with consideration for social, economic, environmental impact

A sustainable city, eco-city, or green city is a city designed with consideration for social, economic, environmental impact, and resilient habitat for existing populations, without compromising the ability of future generations to experience the same. The UN Sustainable Development Goal 11 defines sustainable cities as those that are dedicated to achieving green sustainability, social sustainability and economic sustainability. They are committed to doing so by enabling opportunities for all through a design focused on inclusivity as well as maintaining a sustainable economic growth. The focus will also includes minimizing required inputs of energy, water, and food, and drastically reducing waste, output of heat, air pollution – CO2, methane, and water pollution. Richard Register, a visual artist, first coined the term ecocity in his 1987 book Ecocity Berkeley: Building Cities for a Healthy Future, where he offers innovative city planning solutions that would work anywhere. Other leading figures who envisioned sustainable cities are architect Paul F Downton, who later founded the company Ecopolis Pty Ltd, as well as authors Timothy Beatley and Steffen Lehmann, who have written extensively on the subject. The field of industrial ecology is sometimes used in planning these cities.

<span class="mw-page-title-main">Regenerative design</span> Process-oriented whole systems approach to design

Regenerative design is an approach to designing systems or solutions that aims to work with or mimic natural ecosystem processes for returning energy from less usable to more usable forms. Regenerative design uses whole systems thinking to create resilient and equitable systems that integrate the needs of society with the integrity of nature. Regenerative design is an active topic of discussion in engineering, landscape design, food systems, and community development.

Ecological design or ecodesign is an approach to designing products and services that gives special consideration to the environmental impacts of a product over its entire lifecycle. Sim Van der Ryn and Stuart Cowan define it as "any form of design that minimizes environmentally destructive impacts by integrating itself with living processes." Ecological design can also be defined as the process of integrating environmental considerations into design and development with the aim of reducing environmental impacts of products through their life cycle.

This page is an index of sustainability articles.

Urban metabolism is a model to facilitate the description and analysis of the flows of the materials and energy within cities, such as undertaken in a material flow analysis of a city. It provides researchers with a metaphorical framework to study the interactions of natural and human systems in specific regions. From the beginning, researchers have tweaked and altered the parameters of the urban metabolism model. C. Kennedy and fellow researchers have produced a clear definition in the 2007 paper The Changing Metabolism of Cities claiming that urban metabolism is "the sum total of the technical and socio-economic process that occur in cities, resulting in growth, production of energy and elimination of waste." With the growing concern of climate change and atmospheric degradation, the use of the urban metabolism model has become a key element in determining and maintaining levels of sustainability and health in cities around the world. Urban metabolism provides a unified or holistic viewpoint to encompass all of the activities of a city in a single model.

Environmentally sustainable design is the philosophy of designing physical objects, the built environment, and services to comply with the principles of ecological sustainability and also aimed at improving the health and comfort of occupants in a building. Sustainable design seeks to reduce negative impacts on the environment, the health and well-being of building occupants, thereby improving building performance. The basic objectives of sustainability are to reduce the consumption of non-renewable resources, minimize waste, and create healthy, productive environments.

Ecological urbanism draws from ecology to inspire an urbanism that is more socially inclusive and sensitive to the environment. It is less ideologically driven, than green urbanism or sustainable urbanism. In many ways, ecological urbanism is an evolution of, and a critique of, Landscape Urbanism arguing for a more holistic approach to the design and management of cities. This type of urbanism has a central scope of four main objectives: Compactness, complexity, efficiency, and stability. This model of Urbanism strives to tackle the current challenges of society by intertwining sustainability and urban occupation models. "Ecological urbanism" was coined by architect and planner Miguel Ruano in his 1998 book Eco-Urbanism: Sustainable Human Settlements, 60 Case Studies. The term first appeared as "EcoUrbanism", which is defined as "the development of multi-dimensional sustainable human communities within harmonious and balanced built environments". The term was used later in April 2003 at a conference at the University of Oregon, and again in 2006 in a paper by Jeffrey Hou. Mohsen Mostafavi used the term in the 2007 publication Intervention Architecture and in a lecture at the Canadian Centre for Architecture. Today, ecological urbanism is recognized as a formal academic research topic. Notably, the Harvard University Graduate School of Design has conducted a conference, held an art exhibition, and published a book all centered around ecological urbanism.

<span class="mw-page-title-main">Green urbanism</span> Practice of creating communities beneficial to humans and the environment

Green urbanism has been defined as the practice of creating communities beneficial to humans and the environment. According to Timothy Beatley, it is an attempt to shape more sustainable places, communities and lifestyles, and consume less of the world's resources. Urban areas are able to lay the groundwork of how environmentally integrated and sustainable city planning can both provide and improve environmental benefits on the local, national, and international levels. Green urbanism is interdisciplinary, combining the collaboration of landscape architects, engineers, urban planners, ecologists, transport planners, physicists, psychologists, sociologists, economists and other specialists in addition to architects and urban designers.

<span class="mw-page-title-main">Sustainable urbanism</span> Study of cities and the practices to build them

Sustainable urbanism is both the study of cities and the practices to build them (urbanism), that focuses on promoting their long term viability by reducing consumption, waste and harmful impacts on people and place while enhancing the overall well-being of both people and place. Well-being includes the physical, ecological, economic, social, health and equity factors, among others, that comprise cities and their populations. In the context of contemporary urbanism, the term cities refers to several scales of human settlements from towns to cities, metropolises and mega-city regions that includes their peripheries / suburbs / exurbs. Sustainability is a key component to professional practice in urban planning and urban design along with its related disciplines landscape architecture, architecture, and civil and environmental engineering. Green urbanism and ecological urbanism are other common terms that are similar to sustainable urbanism, however they can be construed as focusing more on the natural environment and ecosystems and less on economic and social aspects. Also related to sustainable urbanism are the practices of land development called Sustainable development, which is the process of physically constructing sustainable buildings, as well as the practices of urban planning called smart growth or growth management, which denote the processes of planning, designing, and building urban settlements that are more sustainable than if they were not planned according to sustainability criteria and principles.

Kenneth L. Haggard is an American architect, educator, and solar pioneer who has designed more than 300 buildings and seen more than 200 built. He is a licensed architect in California and Florida. He and his partner Polly Cooper were awarded the American Solar Energy Society Passive Solar Pioneer Award in 1996. They have been leaders in both passive solar architecture and the rediscovery of straw bale building.

Biomimetic architecture is a branch of the new science of biomimicry defined and popularized by Janine Benyus in her 1997 book. Biomimicry refers to innovations inspired by nature as one which studies nature and then imitates or takes inspiration from its designs and processes to solve human problems. The book suggests looking at nature as a Model, Measure, and Mentor", suggesting that the main aim of biomimicry is sustainability.

Integrated modification methodology (IMM) is a procedure encompassing an open set of scientific techniques for morphologically analyzing the built environment in a multiscale manner and evaluating its performance in actual states or under specific design scenarios.

<span class="mw-page-title-main">Resilience (engineering and construction)</span> Infrastructure design able to absorb damage without suffering complete failure

In the fields of engineering and construction, resilience is the ability to absorb or avoid damage without suffering complete failure and is an objective of design, maintenance and restoration for buildings and infrastructure, as well as communities. A more comprehensive definition is that it is the ability to respond, absorb, and adapt to, as well as recover in a disruptive event. A resilient structure/system/community is expected to be able to resist to an extreme event with minimal damages and functionality disruptions during the event; after the event, it should be able to rapidly recovery its functionality similar to or even better than the pre-event level.

Precise definitions of sustainable construction vary from place to place, and are constantly evolving to encompass varying approaches and priorities. In the United States, the Environmental Protection Agency (EPA) defines sustainable construction as "the practice of creating structures and using processes that are environmentally responsible and resource-efficient throughout a building's life-cycle from siting to design, construction, operation, maintenance, renovation and deconstruction." The Netherlands defines sustainable construction as "a way of building which aims at reducing (negative) health and environmental impacts caused by the construction process or by buildings or by the built-up environment." More comprehensively, sustainability can be considered from three dimension of planet, people and profit across the entire construction supply chain. Key concepts include the protection of the natural environment, choice of non-toxic materials, reduction and reuse of resources, waste minimization, and the use of life-cycle cost analysis.

References

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