Matt Waring

GreenLight Alliance: The Greater Good

In May 2018, LVMH Lighting and Temeloy created ‘Lighting for Good’ (LfG), an eco-design Think Tank, enlisting collaboration from more than 25 lighting suppliers. Its aim is to evolve innovation, services and reliability towards sustainability in the lighting industry. Lucent Lighting was one of these suppliers. 

Acknowledging the energy saving contribution of LEDs to the overall environmental impact of lighting, LfG aims to usher in a new phase of luminaire design concerned with a circular economy. An economy where efficiency in material usage, easier maintenance and plastics removal are the major headings. A LfG charter was written to judge eco-design credentials, with exacting requirements that often exceed the parameters of existing regulations. The principal partner in the writing of this charter was CIRAIG—The International Centre for Life Cycle of Products, Services and Systems. This research group is the centre of expertise on sustainability and life cycle thinking. It brings together the expertise of two universities in Montreal, Canada – Polytechnique Montreal and UQÀM, as well as two universities in Sion, Switzerland – HES-SO and EPFL.

The environmental impact indicators used in the LfG charter are inventoried into a Life Cycle Analysis, a method that quantifies the exchanges between the activities included in a product’s life cycle and the environment, related to the amount of service provided by a luminaire in terms of light output and lifetime. The Ecoinvent v3.6 Lifecycle Inventory Database, released in 2019, was used to generate the trade inventory for a typical fixture. To interpret this inventory, it is converted into environmental indicators, taking into account the potential of each substance concerned to generate an environmental impact. The IMPACT World + method, published in 2019, was used. It involves the calculation of four indicators: 

• Human health (considering the effects of climate change, the use of water, and toxic substances that cause respiratory problems, ionising radiation and depletion of the ozone layer)

• Quality ecosystems (effects on biodiversity of climate change, marine acidification, water and land use, ecotoxic substances and resultant terrestrial and aquatic acidification, fresh water and marine eutrophication)

• Fossil and nuclear energies (use of natural gas, petroleum, coal, uranium)

• Mineral resources (use of non-renewable mineral resources)

The packaging criteria were considered mandatory and were not included in the LCA. 

The individual criterion weight is calculated as the average of the percent reduction for the four environmental indicator scores between the baseline LED fixture system (having the worst value for

the criterion indicated in the charter) and the improved system (having the best value for the criterion), divided by the sum of the individual reductions for all criteria for each indicator. The system modelling considers the whole life cycle of the LED fixture, and a global grid mix for the electricity used during the use stage. 

“As a designer I find this new approach to design very interesting. It is not about the technology available, it’s about us changing our habits, our way of thinking, in this process there is a new paradigm possible,” said Treins.

“Lucent Lighting is proud to have been one of the founding participants in Lighting for Good,” added Morris-Jones. “Originally our involvement was based around our ongoing relationship with the LVMH Group and the network developed by Nicolas Martin (Martin is the Sustainable Store Planning Manager for LVMH; a key role in LVMH sustainable policy. He originated the initiative Lighting for Good). However, over the last three years our participation has turned into something far more significant. 

The initiative has allowed us to use a measured framework based on technical attributes, which provide discipline for our designers, engineers and assembly staff: this has indeed been a company- wide effort. It has resulted in new product designs. We decided to test our progress by entering our newly enhanced MiniTRIM Round in the 2019  ‘Lighting For Good’ Awards.

Having made this decision we organised several design workshops with Tiphaine and decided to address three main topics: efficiency, materials and packaging. We applied for each of these different award categories. The design team, under Gary Parsons, Lucent’s Design Director, started extensive research to find the most efficient COB on the market (with a CRI 90+). Once we found it, we began to see that the design process would not increase our costs but it was an efficient way to analyse each component in our downlight. We simplified the design to be plastic free (except COB) and decided to use a ceramic connector. In doing this we managed to reduce the weight of materials from 310grs to 200grs.

The ‘Lighting For Good’ judging panel recognised the efforts made and we won the Award for ‘Best Materials’. However, the packaging part was one of the areas where we had to change the most. We were encouraged to be plastic-free, including tape, and to use bio-ink.

We are lucky to have a great relationship with our packaging supplier who was also investigating more sustainable materials to respond to the world’s growing demands. This enabled us to quickly respond and we changed not just the packaging but the whole process. We discovered that our normal practice of using two boxes to protect our fixtures was unnecessary with the new paper packing materials and different box sizes: less materials and less time to pack.

In 2020, most of the LfG Think Tank’s onging research was about modularity to encourage thinking about circular economy. So, for the LfG Awards in 2020 we decided to submit a prototype based on our TubeLed Mini spotlight series. We developed a ‘plug and play’ LED module with an easy-to-install system. This provided the first steps to creating more modularity and allowing the possibility to re-use or upgrade the light sources in different ranges of fixtures. For this we were rewarded with the 2020 ‘Lighting For Good’ Best Efficacy Award, which provides an efficacy of 117lm/W using only 5.6W of power.

For us this is a key moment in our design process. We are shifting towards implementing further modularity and designing parts that can be used in different fixture types. We now have the understanding that you do not have to compromise the aesthetics in order to incorporate sustainability and environmental awareness.

In conclusion, thanks to Lighting For Good and its Think Tank, we have been able to be innovative while reducing the environmental impacts of our fittings.

This year, Lucent is looking forward to the Think Tank’s next tranche of work: the financial model.” 

Treins picks up on this theme: “LfG knows that there is an ‘Elephant in the room’ that needs to be addressed. If the fittings can be upgraded or re-used, it is essential to find a new economic model that allows suppliers to continue to grow their business. We already know that it is not a leasing model but more B2B services. The scope of services proposed will probably vary from one client to another. This approach will allow suppliers to create a long-term relationship and adjust to the specific needs of their clients, focusing on reducing their environmental impacts. This new model, to be efficient, will need clients/designers/architects/suppliers to work together toward a remarkable transformation of our production systems and our design and construction process.

Wrapping up, the aim of Lighting For Good and our Think Tank has been to foster innovation whist at the same time reducing the environmental impacts of luminaires. We are seeing that proposing luminaires with LfG ratings in tenders is adding value and driving towards our goal.”

www.lightingforgood.org
www.temeloy.com
www.lucent-lighting.com

Reaction from GreenLight Alliance Members

Mark Ridler, BDP:

"Lighting for Good has much to commend it and its simplicity in output (fair, good, best) makes it something that you could envisage incorporation into other environmental schemes like BREEAM, LEED and WELL and it is great to see the balance between energy, other circular criteria, and quality. There is a danger that it will drive product into a regression toward the mean, for instance, certain beam angles are intrinsically less efficient and yet designers will continue to require a variety of tools in the box. LfG will not be alone in it being more easy to achieve in downlights and spotlights versus linear luminaries for instance, but it certainly challenges product design in a very positive fashion and its good to hear Lucent’s assertion that cost and aesthetics need not be compromised. To maintain a project’s ability to innovate and still keep to circular principles in the majority – it might be an evolution to give a project certification based upon a percentage of LfG product credits.

"To encourage designers to invest the time (and fee) in assessing LfG on a project, we will certainly need manufacturers to engage and readily provide the accreditation information, and so it will become imperative for LfG to grow outside the stable of the 25 early adopters. The LfG charter is open for all manufacturers to use and it will need more to engage if it is to have impact. 

"There are questions too about verification and unscrupulous competition diluting impact, but again this is not unique to LfG. This is a live debate about rigour versus cost of entry and adoption. 

"No walk in the park, “fair” is hard, and “best” is very aspirational. Just as BREEAM evolves its criteria and pegs its “excellent” against a year – so too LfG may need to adopt this to keep the challenge achievable."

Kevan Shaw, EFLA | Kevan Shaw Lighting Design

"It is encouraging to see initiatives like Lighting for Good emerging especially with both manufacturer and designer-oriented tools. Better still at Think Tank level, I feel there should be more lighting designer involvement as well as manufacturers.

"LfG is a scientific assessment of the different environmental impacts of luminaires. As a designer I want to go further and make a judgement not only on the thoughtful use of materials and energy consumption to make a new product, but on the real durability and options for end of first use. I think we need to get answers to questions such as the design life of a lighting product, how long the manufacturer will provide spare parts and any repair and refurbishment service offered beyond the guarantee period. If a refurbishment service is offered what will be the warranty for the refurbished product? Hopefully LfG will manage not only to capture the environmental impacts of a luminaire but also assess the benefit of circular design.  It will require cross-industry input to engage this discussion to develop creative approaches not bound by existing business models and practices.

"I would echo Mark’s comments about a focus on energy use (45.5% of the rating) driving towards a mean that will disadvantage some more useful products, where necessary optical inefficiencies or phosphor inefficiencies such as those that come with warmer colour temperatures, lower the score of a lighting product.

"LfG have boldly launched their charter before other regulations have been published on the quantification of environmental impacts in products. In future it will need to keep a weather eye on or preferably be in correspondence with the emerging thinking in the Directorate of Energy in the EU and BEIS in the UK. Circular economy factors will be included in the next round of lighting regulations, therefore a degree of coherence is required across all systems and metrics in this area to provide clarity to the market on the importance of specific factors and rating systems. The different organisations must coordinate with each other and ensure there is no chance that a product rates well on one and fails another."

by Matt Waring

Three Principles for Healthy Living with Light and Lighting

Amidst the growing awareness of the importance of light and darkness for human health, Asst. Prof. Dr. Karolina Zielinska-Dabkowska and Dr. Ruth Kelly Waskett offer some key advice on how the lighting industry can respond.

The lockdown measures applied to cities and towns during the worldwide Covid-19 pandemic have had a widespread impact on people’s lives. Some have found themselves confined to their homes, with limited social contact and a reduced quality of life. Others have found that the lockdown improved their wellbeing, as more time was spent outside, instead of commuting and working in an office building, plus the benefits of spending increased quality time with loved ones.

The pandemic raised public consciousness about the need to take control of our own wellbeing and health: in particular, to take greater care of immunity. There was also concern about the consequences of extended time spent in indoor spaces, which can create mental fatigue that can manifest itself in a number of ways, including reduced productivity, lack of concentration and in some cases, depression. Many people soon realised the simple things in life that had previously been taken for granted, such as access to daylight and contact with nature, play a vital role in mental health and wellbeing. 

Research in the past two decades has led us to a key moment, where we have a growing body of knowledge about (a) how important daylight exposure is for human health and (b) how damaging electric light exposure at night can be to humans and ecology. It’s now time to put this together and return to the bright day and dark night cycle that evolution engraved in us. 

In the developed world, it is recognised that sleep problems connected to increased light exposure at night are associated with exacerbating existing illnesses and many prevalent diseases. Of great concern is the fact that poor and insufficient sleep has increased significantly in children and adults. Technology, diet and low activity levels are undoubtedly to blame for this, but light is the thread that runs through all of them. During the daytime, not enough time spent outside results in not just low activity levels but also greatly reduced light exposure. At night, interaction with indoor lighting and digital technology leads to an excess of sensory stimuli and light exposure, leading to excess cognitive activity and disrupted hormonal balance before bed.

By and large, people have control over the lighting in their own homes, so it makes sense for lighting professionals to help them make their home lighting environment healthier. The three principles of Healthy Living with Light and Lighting, as introduced here, should support this quest.

What Next?

Lighting practitioners, manufacturers and researchers have an obligation to focus on how to facilitate the recommendations outlined here. We also have a responsibility to help people make healthier choices with light, in the same way that the food industry has a responsibility to help people make healthier choices with food. After many years of campaigning and government policy development, food products must now be labelled with calorie content and nutritional information. Armed with the scientific evidence and knowledge we now have about the impact of light upon human health, it seems logical that lighting products should also provide helpful guidance for consumers. In addition to lumen output, this should include spectral information (SPD), as well as colour rendering index (CRI), correlated colour temperature (CCT) and flicker metrics. Finally, the right to access daylight, coupled with the promotion of healthier light sources in the evening, needs to be implemented into government policies.

Three Principles of Healthy Living with Light and Lighting

Day - Bright Light

•  During the day, try to get exposure to daylight on your face/eyes before 10am, without wearing sunglasses or a hat, to activate your biological clock. This could be achieved by walking outside for a minimum of 30 minutes. Keep in mind that exposure to daylight in the morning will have a direct impact on your quality of sleep at night. 

•  Short-sightedness (myopia) has been linked with a lack of exposure to daylight and time spent outdoors. Exposure to outdoor daylight can also reduce the symptoms of Seasonal Affective Disorder (SAD).

•  As low vitamin D status can be associated with an increased risk of Covid-19 infection, from late spring to early autumn, try to gradually increase your skin exposure to direct sunlight for 5-10 minutes each day to produce vitamin D. Note that at high latitudes in winter, it is not possible to produce vitamin D from sun exposure, therefore supplementation with vitamin D3 is necessary.

•  In indoor spaces, try to rely on daylight as much as possible, and position your desk next to the window, preferably with a view out, especially when you have to work long hours. If daylight is unavailable, use electric lighting that provides a continuous spectrum of light with a high blue wavelength content, to mimic aspects of the spectral composition of daylight. 

Evening - Less Light

•  During the evening at home, use lighting with a warm colour appearance at night and a Correlated Colour Temperature (CCT) below 3000K. Allow for a mixture of ambient and focal lighting, ideally with a continuous light spectrum and very little to zero blue wavelengths of light. Use dimming to lower light levels and create a relaxing atmosphere.

•  Use LED light sources with continuous light spectrum, rather than compact fluorescent lamps (CFLs).

•  Blue light from electronic devices can supress the production of melatonin and adversely impact your sleep. This is particularly important in children, for whom sleep disturbances can severely impair and reduce the production of growth hormone, and hinder memory function. It is the interaction with technology, however, that matters most. Avoid using mobile devices such as mobile phones or tablets for two hours before bedtime. If available, features such as “night shift”, which reduce the blue energy content of the light emitted from a device screen, can be used. Such features, however, do not completely reduce the blue wavelengths of light, so will not completely mitigate the impact of such devices.

Night - No Light

•  Sleep should take place in complete darkness, preferably with no electric lighting. If any light trespass from street lighting is present in the bedroom, use blackout curtains or window shutters, or wear an eye mask to minimise it.

•  The National Sleep Foundation (NSF) recommends that the best time for getting ready for bed is between 8pm to 12am. The hours of sleep before midnight have been shown to benefit organ function.

•  If you need to use the bathroom during the night, use yellow, amber or even a red coloured light source with zero blue wavelengths of light in the spectrum, and ensure the light source emits diffused, low levels of light.

•  Try to get at least seven hours of undisturbed sleep. REM sleep phases last around 90 minutes, meaning four full sleep phases. Good quality sleep is particularly vital during illness, because the regeneration and repair of cells occurs during sleep. Sleep also boosts the body’s metabolic rate to facilitate weight loss, and several studies have linked exposure to artificial light at night to weight gain and obesity. 

References

• Argys, L.M.; Averett, S.L.; Yang, M. Light pollution, sleep deprivation, and infant health at birth, Southern Economic Journal 2021, 87, 3, pp 849-888. https://doi.org/10.1002/soej.12477

• Brown, T. et al. Recommendations for Healthy Daytime, Evening, and Night-Time Indoor Light Exposure. Preprints 2020, 2020120037 https://doi.org/10.20944/preprints202012.0037.v1

• Changing perspectives on daylight: Science, technology, and culture. Science/The American Association for the Advancement of Science, Custom Publishing Office Washington, DC, 2017. 

• Commission Internationale de l’Eclairage (CIE). CIE Position Statement on Non-Visual Effects of Light. Recommending proper light at the proper time, 2nd ed,. CIE Publication: Vienna, Austria, 2019; Available online: https://bit.ly/2NysTq0 (accessed on 17 March 2021).

• Graw, P. et al. Winter and summer outdoor light exposure in women with and without seasonal affective disorder. Journal of affective disorders 1999, 56, 2-3,163-169. 

• Grubisic, M. et al. Light pollution, circadian photoreception, and melatonin in vertebrates. Sustainability 2019, 11, 6400. 

• Lagrèze, W. A.; Schaeffel, F. Dtsch Arzebl Int. 2017,  114, 575–580. https://doi.org/10.3238/arztebl.2017.0575

• Liu, N. et al. Low vitamin D status is associated with coronavirus disease 2019 outcomes: a systematic review and meta-analysis, International Journal of Infectious Disease 2021, 104, 58-64. https://doi.org/10.1016/j.ijid.2020.12.077

• McAlpine, C.S., Kiss, M.G., Rattik, S. et al. Sleep modulates haematopoiesis and protects against atherosclerosis. Nature 2019, 566, pp.383–387. https://doi.org/10.1038/s41586-019-0948-2

• Münch, M. et al. The Role of Daylight for Humans: Gaps in Current Knowledge. Clocks & Sleep. 2020, 2, 61-85. 

• Park, Y.M.M. et.al. Association of exposure to artificial light at night while sleeping with risk of obesity in women. JAMA Intern Med; 2019, 179(8), pp.1061–1071. 

• Wright, K.P. et al. Entrainment of the human circadian clock to the natural light-dark cycle. Curr Biol. 2013, 23, 16, 1554-1558.

• Zielinska-Dabkowska, K.M.; Xavia, K. Protect our right to light. Nature 2019, 568, 451–453. 

• Zielinska-Dabkowska, K.M. Make lighting healthier. Nature 2018, 553, 274–276. https://doi.org/10.1038/d41586-018-00568-7

• Zielinska-Dabkowska, K.M. Vitamin D. The truth about Vitamin D and sun exposure demystified. Finding the balance for personal health. Professional Lighting Design 2014, 93, 40-48. 

• Zielinska-Dabkowska, K.M.; Rohde, M.F. (Eds.) New Perspectives on the Future of Healthy Light and Lighting in Daily Life., 1st ed.; callidus. Verlag wissenschaftlicher Publikationen.: Wismar, Germany, 2017; ISBN 978-3-940677-61-7 https://bit.ly/3bWg5Dh

• Zielinska-Dabkowska K.M. Home Sweet Home. Connecting the dots for healthy evening residential illumination. arc magazine 2019, 111, pp.055-060. ISSN 1753-5875 http://bit.ly/30TqCss

by Matt Waring

On Guard for Lighting Quality: The establishment of the first association of professional lighting designers

Asst. Prof. Dr. Karolina M. Zielinska-Dabkowska IALD, IES, CIE, MSLL, RIBA, looks at today’s recognised lighting design profession and its historical formation combining aspects of science and art.

Not many people in the lighting community are aware of the fact, that after electricity was invented and in general use in the United States from the late nineteenth century, only electrical engineers were responsible for the illumination of architecture. After 1906, when the Illuminating Engineering Society of North America (IESNA) was established in the USA, companies and individuals professionally involved in the field of gas lighting and natural light, were first brought together. However, this new field quickly became dominated by people applying electric light in their projects. 

Members of this young discipline were mindful from the beginning, that a collaboration with architects was decisive and of great importance for the future development of lighting as a profession. One of the tasks that was set was the promotion of cooperation between these two professions in the field of architectural illumination. This included the presentation of completed projects, the monthly publication of articles in “Transactions of the Illuminating Engineering Society”, and the participation in annual conferences related to the topic of artificial illumination. In order to control the chaos of illuminated advertisement that began to flood New York, the first rules were introduced to regulate external illumination. However, architects of this period seemed rather reluctant to cooperate with illuminating engineers, as they did not want to bear the cost of additional consulting services. For many years, the relationship between these two groups was strained. Interestingly enough, the subject of architectural lighting initially did not appear in the architectural press at all. Instead, it was present on the front pages of journals and in technical journals related to the electrical industry. As the wave of lighting installations gradually spread across America, and later, also across Europe, even more of such publications were printed.

Meanwhile, on the other side of the Atlantic, in several other countries, similar associations of lighting specialists were established. First, in 1909, the Illuminating Engineering Society was founded in London, then in 1912, the German Society of Lighting Technology was established in Berlin. Later, the Illuminating Engineering Institute of Japan was founded in Japan in 1916, and then in Poland, in 1924, the Polish Electrotechnical Committee was created, which five years later, was transformed into the Polish Committee of the International Commission on Illumination.

In the IESNA professional press, there was a heated polemic between members of the association on the direction of the development of this new profession. Most wanted to follow the functional lighting path, including technical aspects, such as the amount of light and functional needs: “There is a large field for the illuminating engineer where aesthetics is only of secondary importance: in this field [he] may achieve success even though he does not concern himself personally with purely artistic side of the work.” [1]

In addition, some members believed that there was no need at all for an illuminating engineer to be creative: “An [illuminating] engineer, by reason of his education, is unsuited absolutely for the work [artistic illumination of architecture], which he sets out to do. 

“He has no conception of the effects desired. He has no creative ability, no knowledge of the history of architecture and history of ornamentation, and in fact, he is working in the dark absolutely.”

Some members of the engineering community thought the architect should impose his ideas on these matters in such a way that the engineer follows his recommendations, because such cooperation will bring the most effective results in accordance with the direction set by the architect: “[...] the architect feels he should dictate in such matters, and that the engineer should follow his dictates, and this will produce the most efficient results along the lines laid down by the architect.” [2]

However, there were also new and differing opinions. First of all, there was a call for quality aesthetic solutions in illumination design as well as an artistic design approach, built on understanding of the architectural concept: “This branch of illuminating engineering is unquestionably an art, and only a science in so far as an art is scientific in its method. The illuminating engineer who hopes to cope with the lighting features of architectural problems, must be familiar with architecture.” Some professionals were also calling for better education of illuminating engineers to perform their new duty: “How, then, is the illuminating engineer successfully to cope with his problem and advise with the architect as to the best means of achieving results, if the engineer cannot appreciate and understand the architect’s viewpoint? […]. It seems, then, that a very important, if not essential feature of the engineers’ preparations is a study of the history of illumination and its relation to architectural design”. [3]

People who preferred these ideas explored the art of “painting with light”. Their lighting projects stood out because they were unusual, aesthetically refined, and brought out the beauty of architecture during the night hours. It was believed that: “The illuminating engineer who considers only the scientifically practical side of the profession is necessarily doomed to ultimate failure, for he will not be able to obtain the recognition that the importance of his work deserves.” [4] 

There were also voices that postulated renaming the profession: “Viewed in its broader sense it would seem that the term <illuminating engineer> is not entirely suited to the profession, but that <lighting expert> or <lighting specialist> would more fittingly describe the broad scope that the profession should cover.” [5]

E.L. Elliott, one of the IESNA members, promoted the need for an architect to employ an illuminating engineer, explaining that “architect” means “master-builder”, and therefore, the building consists of many elements, the details of which, must be more or less known to the architect. The special task is to make all the pieces fit together, properly coordinated, so that the final result is successful and complete. In 1908, Elliott wrote: “The number of elements entering into the structure and design of modern buildings is vastly greater than anything conceived of in ancient or medieval times. With this great increase in the elementary problems has come a demand for corresponding greater knowledge of details, with the result that, in many cases, the requisite knowledge has broadened to such an extent as to render a sub-division necessary in order to leave the master-builder free to follow his legitimate office of co-ordinating the various details. This has given rise to an increased number of specialists, or engineers; and the latest among these is the illuminating engineer.” [6]

As a result of many activities undertaken in the 1920s and 30s, there was an unexpected change in the attitude of architects. This spurred a fascinating cooperation between illuminating engineers and architects. The illuminating engineers also understood that to better serve architects, they must have basic architectural knowledge. For the first time in 1930, two series of lectures related to the basics of architecture and field trips were organised for IES members in New York and Chicago, led by practicing architects and professors of the schools of architecture of the University of Illinois and the Armor Institute in Chicago and Columbia University in New York. [7] “The Illuminating Engineering Society believes that in order to be of real service to the architect, the illuminating engineer must know more about the architect’s problems and be able to talk to the architect in his own language. He should also be conversant with architectural terminology and have some knowledge of the fundamentals of that subject.” [8]

Professor Harold Vandervoort Walsh of Columbia University’s Department of Architecture described the relationship of these two professional groups: “Architects do not seek to light every corner of their building. Shadows to them are as important as light. The new movement in lighting has come about as the engineer, busy with his problems of lighting efficiency, has looked beyond and realised that the architect wanted this playfulness and emotional quality of light. On the other hand, the architect, seeing a friendly face, has turned away from his old-fashioned ideas about lighting and had awakened to the fact that the engineer has developed for him newer and finer ways of playing with light.” [9] 

Walsh also emphasised the expectations and concerns that architects usually have: “The [illuminating] engineer will not classify the apparently impractical and novel ideas of the architect as foolish, but will sit down and figure out how to do them. From the flights of imagination of artists come the problem for the scientists. [The architect’s] mind will be cantered upon the best way to bring out the forms he has designed by good lighting. He will not get far with an engineer who answers his questions with, “it can’t be done”. But great progress will be made with a sympathetic engineer at his elbow, interested in helping him achieve an ideal.” [10]

This first step in the cooperation process was pivotal. However, architects were still, in most cases, the originators of the illumination concept, and the illumination engineers supported them with advice on how to achieve a particular lighting effect. For instance, where to place the luminaires, what type of luminaires to use, and what materials on the façade will be the most advantageous. Special models were also created, so it became possible to present the effects of illumination. However, the services provided by the illuminating engineer were still limited to technical advice, not to independent, creative work.

There were two Americans in the early history of electric lighting who were pioneers of the newly emerging movement. One was Walter D‘Arcy Ryan, Director of the Illuminating Engineering Laboratory at General Electric who was known for his skyscraper illumination, as well as larger projects including the 1915 Panama-Pacific International Exposition in San Francisco, or the Century of Progress Exposition in Chicago (1933-1934). Another was Bassett Jones, who was a key figure among architects active in the 1920s and 30s. Jones was an all-round engineer, inventor, theatre and architectural lighting designer. He was also a member and founder of IESNA, and one of the first to speak about key issues involving architectural lighting. He insisted on the cooperation between an illuminating engineer and an architect. Thanks to the influence of both these visionary people, interest in lighting increased in the first half of the 20th century. Yet, despite their obvious success, the profession of lighting designer remained unrecognised as an established career.

When analysing the literature, it’s clear it was really only the architects of modernism operating in the second half of the 20th century, who considered illumination to be an important tool in creating an architectural form. Additionally, there was the need to create a new specialisation because knowledge about lighting technology became too broad for the architect of the building to study, or to rely only on consultancy from the illumination engineer, as had been the standard practice. 

The consequence of this was the conscious use of the services of a lighting designer where this professional would initiate the dialogue in the early stage of the design process. At that time, the style and trend of modernism proposed new, bold solutions with materials and technology, which formed an excellent contribution to the development of this new profession.

Although the number of people in America who dealt with the professional lighting of architecture continued to increase, it was only at the beginning of 1968, that the first attempts were made to institutionalise this field of lighting design. Even though many individuals created innovative work, the profession remained largely unrecognised. Initially, faced with the challenge of securing their future, a small group of passionate and inspired pioneers from New York, met monthly for informal gatherings in Manhattan restaurants, private apartments, and conference rooms, to define their new profession, and to set future goals for development.

The first meeting was at Richard Kelly’s home. The same individual known for his concept of “layers of light” or the approach of integrating three distinct types of lighting: ambient luminescence, focal glow, and play of brilliants. [11]

Most who attended had an architectural and theatrical training/background and were members of IESNA, yet they chose to connect in recognition of their unique position. Their services differed from those of electrical engineers or illuminating engineers, as their skills involved the design, application, and use of lighting that was in harmony with architecture - this was a combination of science and art. The initial goals of the emerging organisation were thus defined: “[…] to do all acts and things necessary to bring together practicing professionals in the field of lighting design; to define, develop, advance and maintain standards and excellence among Association members; and to communicate these ideas and the attendant benefits of designing lighting to allied professions and the public at large.” [12]

In 1971, the International Association of Lighting Designers (IALD) was officially incorporated, with its headquarters in Chicago, USA. Today, members of this professional organisation are designers with an education in the field of architecture, interior architecture, theatre, electrical engineering, as well as lighting design. The association unites more than 1,500 independent, professional lighting designers from all over the world. The association’s mission is to advance the global profession through advocacy, creating global standards for lighting design excellence. It promotes excellence in lighting design through the work of its members, who make a huge contribution by providing innovative and responsibile lighting solutions. These designers understand the role of lighting in architecture, interior design, and urban and landscape design, and they use their rich experience and knowledge to raise the profile of these projects. Today, as it was in the past, professional members of the IALD cannot also be involved in any way, in the sales of lighting products. Their earnings are derived from design services, which gives them complete independence in choosing the best aesthetic and technical solutions, whilst also supporting needs of humans and the external environment.

References

[1] Jones B., The relation of architectural principles to Illuminating Engineering Practice. Transactions of the Illuminating Engineering Society, 1908, vol. III, p. 9.

[2] ibid. p. 42.

[3] ibid. pp. 25-26.

[4] ibid. p. 9.

[5] ibid. p. 50.

[6] ibid. p. 55.

[7] Architect and Illuminating Engineers Break Bread together, Reflections. Transactions of the Illuminating Engineering Society 1920, no. 7, p. 749.

[8] Transactions of the Illuminating Engineering Society, 1930, no. 6, p. 535.

[9] Walsh H. V. An Architect’s reaction to the new movement in lighting. Interim Report –

Committee on Light in Architecture and Decoration. Transactions of the Illuminating Engineering Society 1930, no. 7, Vol. XXV, pp.

603–604.

[10] ibid. pp. 603–604.

[11] Zielinska-Dabkowska, K.M. Home Sweet Home. Connecting the dots for healthy evening residential illumination. arc magazine 2019, no. 111, pp. 055-060. http://bit.ly/30TqCss

[12] International Association of Lighting Designers (IALD). Celebrating 35 Years of Lighting Design Excellence, 35th Anniversary Yearbook, Chicago 2005, p. 4.

by Matt Waring

IALD: 3D Printing - an integral part of the luminaire design process

Frederik Friederichs, Group Manager at Light Bureau, explains more about his first steps into 3D printing luminaires.

It all started with a replacement part for a linear fluorescent tube. While browsing through a luminaire storage, checking for functional luminaires to salvage, I discovered a classic T5 luminaire with a missing end cap. It was a merely aesthetic flaw since the luminaire was functioning fine otherwise, and I was sure that this would be an opportunity to start investigating into 3D printing to allow me to reproduce this specific part of the luminaire. The scope was identified with a measurable goal and I tried to reverse the design process to build a duplicate from the existing end cap.  

In all beginnings and when entering a new production method with different workflows, roads are bumpy and the first steps are unavoidably subject to multiple trial and error processes. But I felt that 3D printing can become an essential part of our design exploration process to find suitable dimensions, shapes and forms and serve to understand the production and creation process better. 

From Idea to Form

Purchasing a sliding caliper immediately became useful when starting detailed measurements on luminaire parts. The end cap had a rather simple cylindrical shape with delicate mounting bits in the bottom to connect to the socket base. After reviewing the first 3D printed part from the 3D file I had generated, I was caught by surprise.  

The 3D printer is capable of spitting out a digital model, transforming data into a tactile product. But the quality of the result was far off from my expectations, with exception of form and material thickness of the generated object. This led me to analyse the piece in detail, revising the modelling workflow and the transition into the “slicer” (the programme that translates the 3D model attributes for the 3D printer). Following these steps, I was able to refine the surface structure and quality, optimise the necessary support structure to print this piece and get consistent results. It took a few attempts to figure out the correct tolerances to make the end cap snap onto the socket without using too much force. Simultaneously, I was interested in trying different material types with a variety of characteristics besides the polylactic acid (PLA), which is most commonly used in the FDM (fused deposition modeling) 3D printing process and engaging in online learning courses that helped me to calibrate and utilise the 3D printer more efficiently.  

It still feels like scratching the surface of options and opportunities connected to 3D printing, since the possibilities and knowledge exchange in the field of 3D printing are endless. But these first iterative steps to arrive at an adequate and bespoke 3D printing part made me more interested in more complex tasks. 

From Form to Fit 

My creative process was certainly boosted by changes around the office leading to closer cooperation with the architectural studio GPA (part of AFRY). In 2019, we started to extend the 3D printing hardware in our common workshop/light lab at the office, allowing faster and larger 3D prints. It helped us to react instantly on projects where we wanted to apply customised fittings. We were able to deliver mock-ups and conceptual solutions ranging from luminaire brackets to reflector parts. In this stage we mainly used the 3D printing capabilities to make tests and give clients an idea of scale and form of the final tailor-made product part. Due to its rapid and almost instant nature, additive manufacturing supported our decision-making process. The awareness of 3D printing was rising, and we even cooperated with manufacturers who sent us 3D data of additional luminaire parts for mock-up luminaires, since it was faster to produce these add-ons locally than to send the spare parts to us by post. This made me realise that 3D printing can become a major part of a circular economy system and a sustainable alternative for the existing linear production due to its decentralised production capabilities. 

The focus changed from just using the technology to replace or supplement parts to designing a 3D printed object first, which could then be produced in series.  

From Fit to Product

Materialising ideas and the production of custom-made parts has become significantly easier and more accessible through additive manufacturing. We are now able now to react and adapt to changes in the detailing stage and proactively find solutions for difficulties and issues at the project site. But to allow a higher print volume, more accuracy and sturdiness for the object, while reducing costs and production time per piece, we were looking for partners using suitable 3D printing technologies to cooperate with.

Ruten in Sandnes

One of the new signature structures in Sandnes, a city located on the west coast of Norway, will be Ruten, which has long been the region’s largest transit interchange point. The area has undergone an extensive infrastructural transformation, leading to a new key pivot point for the city featuring an urban park with a canopied ring structure. The design brief in this project, developed and designed by SpaceGroup Architects in Norway, was to install luminaires at predefined heights into approximately 60 round pillar cavities of a filigree bearing roof structure with an organic shape. The lighting concept for the urban area focuses on using mainly indirect reflected light from the canopied structure provided by the pillar integrated luminaires, resulting in a soft and diffuse lit area providing guidance and orientation while simultaneously highlighting the volume of the structure. 

We are currently in the final stage of completing this project – our first where 3D printing is a vital and integral part of the fixture design.

The diameter for the prefabricated cut-outs in the pillars was defined to be 10cm and the difficulty of this task was to create a luminaire component that seamlessly connects the convex shape of the pillar and holds an adjustable standardised exterior spotlight fixture firm in place. Additionally, other challenges, such as different material thickness of the pillars and the fact that all components needed to fit through the 10cm hole as only access point, influenced the design process for the prototype. 

After plenty of considerations and numerous design alternatives with regards to optimised light distribution, colour, fitting and installation, as well as in regard to the workflow for the electrician, were carried out and we arrived at a final design solution with a consistent and coordinated design for a prototype in January 2020. A mock-up was subsequently performed in a warehouse and all project participants were able to see this hybrid solution of a tailor‐made 3D printed secondary reflector and a standard exterior spotlight.  

Together, with the producer of the 3D prints, we discussed object joints and fillets, material choice and thickness as well as tolerances to be able to deliver a holistic and comprehensive design that is long lasting and easy to install and maintain on building site. Funnily enough, the producer is located 20km from the building site, a fact that became significant in the beginning of February 2021. 

After all components were delivered to the site, we received a phone call informing us that the cut-outs in the pillars were performed through a different method, resulting in higher tolerances of the cut out down to around 8cm. We managed to tackle this deviation by redesigning and adjusting the secondary reflector and could deliver new prototypes on site for fitting within three days, without the need to wait for a shipment from further away.  

We expect the project to be done in the first quarter of 2021 and are looking forward to the results. I am of the opinion that we have not yet leveraged all of the possibilities that lie within the 3D printing technology. We are on the verge of making 3D printing a powerful element in the lighting designer’s toolbox.

www.iald.org

by Matt Waring

David Morgan Review: LED Linear Ultima-P

LED Linear shrinks luminaire design to a new level with its latest range, Ultima. Originally due to launch during Light + Building 2020, the Ultima range has now been revealed virtually. David Morgan delves in to find out more. 

The world of lighting changes fairly gradually but one continuous trend that I have experienced over many years of luminaire design is the miniaturisation of luminaires and light sources. LED Linear has always achieved a high lumen output from small profile products and has now taken luminaire shrinking to a new level with its Ultima range.

LED Linear was founded by Dr. Michael Kramer, who was responsible for sales and marketing, and Carsten Schaffarz, who looked after innovation and production. They were colleagues at Vossloh-Schwabe Optoelektronik before launching LED Linear in May 2006, initially operating from a garage. The company has rapidly grown to become one of the most recognised brands in the specification linear lighting market, with 150 directly employed staff. The company was acquired by the Fagerhult Group in 2016 and, after three years transition, the two founders have now moved on.

LED Linear has based its systems on the use of flexible LED tape, which is assembled in-house, along with all the various luminaire types at a facility in Duisburg, Germany. Sales are global with branch sales offices in major markets and a network of distributors in smaller countries.  

The latest luminaire series to be launched by LED Linear is the Ultima range that was due to be launched at Light + Building  2020 but which, due to the Covid pandemic, has been launched virtually.  The complete range, which has a very wide range of housing and mounting options, all incorporate an innovative, miniature, linear light engine and heat sink assembly only 13 mm wide x 10 mm deep.  The heart of the Ultima range is the light engine, which incorporates chip scale 1mm x 1mm 0.2W LEDs mounted on an 8.5mm pitch.  It is understood that LED Linear is the only manufacturer so far that  has been able to mount chip scale LEDs onto a flexible PCB with the required precision to work correctly with optics. The light output from the LEDs is controlled with a miniature moulded reflector, only 7mm in diameter, and a nano lens optical film combination. The light engine is mounted in an extruded aluminium heat sink housing onto which a moulded miniature glare control louvre is fixed, providing glare control up to UGI 13. The NanoRay 2 optical film used in the Ultima is understood to be a further development of the earlier nano optic system used in the LED Linear Mars system.

There are seven distributions available in the Ultima range, from a narrow 10º spot up to a wide 60º beam and an opal window option for a diffuse effect. There are optics for batwing and asymmetric distributions, allowing the system to be used in a wide variety of lighting applications.

Maximum output is 1,870 lumens from the 4,000 K 80 CRI version with a power consumption of 25W per metre. 

The Ultima S range - the stand-alone version - was the first to be launched in 2020. This is the basic 13mm x 10mm profile, which can be mounted with various clip designs and also magnetic strips that can be fixed with double sided adhesive tape to the body extrusion.  Specific clips allow this version to be mounted onto T-bar ceilings where the width of the luminaire fits unobtrusively between tiles

The Ultima T track mounted range was then launched. This combines a four conductor low voltage track system with the Ultima luminaires allowing them to snapped in and repositioned as required without tools. Suspended, surface mount, and trimless recessed versions of the track are also available.

The latest version is the Ultima P pendant version, which I was given to test. In this instance the linear strip is mounted in a robust steel U channel to provide additional weight thus making a very neat pendant. 

The samples I was given were the medium flood with a 40º beam and black louvre, and the batwing distribution fitted with a white louvre. The lit effect of the 40º distribution was fairly dramatic producing a high intensity cut off beam, which was uniform and has  almost no visible colour over angle issues. The batwing version was equally impressive with a wide clean distribution.  

One of the advantages in reducing the size of luminaires, in addition to production cost reduction, is to minimise the environmental impact and carbon footprint by reducing the weight of materials used. The Ultima range would fit well into a circular economy model as the mechanical and optical components all snap together very neatly. However, I am not sure how easy it would be to remove the LED tape from the heat sink extrusion after five or more years in use.

It is understood that the Ultima range was developed over a two-year period following discussions with lighting designers in various countries who expressed a strong interest in specifying smaller luminaires with high output and good optical control. The Ultima design and development was undertaken in-house with the top management team involved throughout the process. Franziska Heckmanns was the key product designer for the range,  I understand.

The company reports that feedback from lighting designers and customers has been positive to the Ultima range and a number of projects have already been completed. This latest example of luminaire miniaturisation has been well executed and looks set to be a successful addition to the LED Linear portfolio.

www.led-linear.com

by Matt Waring