1. Introduction

On 16 September 2020, the new president of the European Commission, Ursula von der Leyen, made a speech on the state of the Union in which an ecological, economic, and cultural project called the New European Bauhaus (NEB) was announced [1]. It is an initiative that combines design, ecology, social, and price accessibility aspects as well as investments in order to support the implementation of the European Green Deal (EGD) [2]. The name, referring to the Bauhaus—the German arts and crafts school from the first half of the 20th century, signals a common source of inspiration, which is the need to develop in the face of social and technological changes taking place in the world. The recently celebrated 100th anniversary of the founding of the Bauhaus was, therefore, an excellent excuse to re-look at its heritage, especially in the context of a holistic approach to design. The beginning of the return to the Bauhaus is the idea of the Baukultur movement, developed for over 20 years and formally initiated in Germany as the Federal Baukultur Foundation. It aims to combine a high standard of design with a holistic view of social, economic, environmental, and cultural aspects. Creating Baukultur is a social process based on a broad understanding of values and goals and high-quality interdisciplinary discourse [3]. The signing of the “Declaration Towards a High-Quality Baukultur for Europe” in 2018 in Davos, the inclusion of Baukultur in the work of the European Council, the elections to the European Parliament, which were dominated by problems related to the climate crisis and the development of the poorer parts of Europe, and, eventually, the COVID-19 pandemic have shifted the center of gravity of the upcoming changes to connect Baukultur with the challenges of climate protection and the recovery of the economy after the pandemic, which may be an opportunity for a fresh start.

The first part of the “Sixth IPCC Report”, published on 9 August 2021, unquestionably states that global warming is a result of human activity and recalls the conclusions of the previous report on the need to reduce CO₂ emissions to a net-zero level [4]. Since construction, as part of the economy, is responsible for a significant part of these emissions (38%) [5], the success of achieving this goal depends on actions in this area.

In this context, the activities of the European Commission are up-to-date, and the goal of achieving climate neutrality by 2050, presented in the EGD, is ambitious on a global scale. The founder of the Bauhaus, Walter Gropius, argued that the projects should enable the expression of thoughts and moods of their time, which, at the beginning of the 20th century was, for example, the growing demand for inexpensive and healthy housing, to which prefabrication was supposed to be the answer [6]. In the case of the New European Bauhaus, the problem is the climate crisis, and the answer to how to solve it is still sought; hence, the NEB is to be a platform for the development of new ideas. It is to create a bridge between the world of art and culture on one hand and the world of science and technology on the other; this will involve the whole of society: artists, students, architects, engineers, scientists, and innovators. It is supposed to be a system change [1]. Additionally, since every change requires education, teaching environments need to respond to new challenges and integrate curricula with the requirements of the upcoming change.

2. Bauhaus Ideas as a Response to the Challenges of the Early Twentieth Century

The name Bauhaus, founded in 1919 in Weimar by Walter Gropius, an art and craft school, refers to the medieval organization Bauhütte, associating bricklayers, stonemasons, carpenters, and other craftsmen working on large construction sites. It was not a coincidence because the Bauhaus was supposed to be a return to artisanal tradition in the spirit of the Art And Crafts movement founded in 1988 in England, promoting the creation of art both aesthetic and useful, but without its opposition to industrial production. On the contrary, Bauhaus wanted to combine the achievements of modern technology with art, thus creating a concept of modern industrial design.

Despite the short period of activity (1919–1933), the school developed a mature educational program, the aim of which was the ability to holistically design objects or buildings that meet the needs of a changing society, taking into account the technological development of industry and, at the same time, durable utility and aesthetic values. To implement this modern approach to design, a modern teaching system based on outstanding designers and a collective sense of common purpose was also needed. The school functioned for only a dozen years, but it was created, apart from Walter Gropius, by outstanding lecturers, including Paul Klee, Wassily Kandinsky, László Moholy-Nagy, Marcel Breuer, and Ludwig Mies van der Rohe, who was the last of its directors. The program had many consistent features, e.g., parallel theoretical and practical learning of crafts; interdisciplinary learning, with many lecturers working on one project; working together in groups and even living together [7]; use and synergy of many additional arts and cultural elements such as dance, poetry, music, costumes, leading to a sense of inner bonds, solidarity, and a sense of mission and responsibility among the participants. Thanks to this, the ideas of the Bauhaus were durable and could develop effectively, transferred by its members to other countries, even after the school was closed by the Nazi authorities in 1934. The ideological and design achievements of the Bauhaus, despite its short period of operation, had a huge impact on the development of the art of design, bringing about various projects (Figure 1), ranging from simple household appliances (Wilhelm Wagenfeld lamps (1923)) and furniture (e.g., Wassily (1925–1926) and Cesca (1928) chairs by Marcel Breuer, the Barcelona armchair (1929) by Mies van der Rohe) to buildings (ending with the headquarters of the school in Dessau (1926, designed by Walter Gropius), house Haus am Horn in Dessau (1923, designed by Georg Muche), and the Barcelona Pavilion (1929, designed by Mies van der Rohe)).

The idea of universal education consisting of the gradual acquisition of skills—from general to specific, including teaching history only at the final stage of studies so as not to discourage and not restrict the ideas of younger students, made it possible to acquire universal skills in solving design problems in all areas. This gave rise to the development of modern design, which is ubiquitous today. These days, people trained in design have gained access to a very wide range of professions, and, together, they exert a tremendous influence in positions of senior management, government, and academia. It is a testimony to the quality of design practices and the importance of design education in contemporary society [8].

3. Challenges of the New European Bauhaus in the Context of the Bauhaus School

One of the tools supporting the achievement of EGD goals is the ecological, economic, and cultural project of the New European Bauhaus (NEB), the design phase of which was launched in January 2021. Its most important values are sustainable development, aesthetics, and social participation, and the aim of the design phase (first half of 2021) is to search and define the final shape of the initiative, which will be implemented in five European countries in subsequent phases and, finally, promoted in the EU and beyond its borders. The NEB is to initiate a new approach to the most important challenge of our time—the climate crisis. This approach is to be modeled on the principles used in the Bauhaus school, as shown in the comparison in Table 1:

Therefore, it is necessary to emphasize the great ideological similarity between the NEB and Bauhaus. Today, after 100 years, the challenges facing society have changed, but the way of solving them is universal and, most importantly, holistic, based on the cooperation of specialists in many fields to re-shape the technology, economy, and culture of Europe in line with the objectives of the EGD.

4. Objectives of the European Green Deal in the Context of Sustainable Design

The European Commission’s legislative initiative, the European Green Deal (EGD), aims to adapt the EU’s climate, energy, transport, and tax policies to meet the goal of reducing net greenhouse gas emissions by 2030 by at least 55% compared to 1990 levels. This very close time horizon requires European countries to take decisive measures, which in the field of construction, according to the European Commission, are primarily the decarbonization of the construction sector, the renovation of existing housing stocks, increasing the energy efficiency of buildings (reduction of final and primary energy consumption by 36–39%), and increasing the share of renewable energy sources (up to 40%) [13]. In addition, on 14 July 2021, the European Commission adopted a package of proposals called Fit for 55, summarizing the above projects and giving them an even more specific legal framework. In addition to the above-mentioned goals for 2030, new goals [14] were presented, including:

• the share of renewable energy sources in buildings should be at least 49%;

• increasing the use of energy from renewable sources in heating and cooling by 1.1% per year;

• increasing the use of renewable energy in district heating and cooling systems by 2.1% per year;

• reduction of energy consumption in the public sector by 1.7% per year;

• reduction of primary energy consumption by 39%;

• reduction of final energy consumption by 36%;

• renovation of 3% of public buildings annually.

The European Commission has divided the challenges of the EGD into several areas of action: Climate, Energy, Agriculture, Industry, Environment and Oceans, Transport, Finance, and Regional Development, Research, and innovation. Achieving these goals will require European countries to take decisive actions for which specialists will be needed; some of them will cover areas that are the subject of architectural activities. The European Commission estimates that 160,000 new jobs will be created in the construction sector alone to meet the building modernization target [13]. This requires considerable effort to educate future architects as well as academic staff. As research shows, there is a need to educate academic staff for sustainability leadership as well as to update curricula with the simultaneous definition of the concept of sustainability. It is pointed out that the principles of Education for Sustainability (EFS, [15]) are still far from being integrated into the everyday practices of academic staff, and one of the main reasons for this is the complexity, ambiguity, and multidimensionality of the concept of sustainable development, which makes it difficult for individuals to understand why and how to implement sustainable development in practice or how to educate for sustainable development [16].

In the case of the author’s study, it was decided to define the concept of sustainable design in relation to the goals presented in the EGD initiative. The following areas and goals of initiatives have been identified in relation to the features of sustainable design to achieve them:

The summary indicated in Table 2 shows that the objectives and areas of activities of the EGD and the NEB supporting it are consistent with the principles of sustainable design. On this basis, a method of teaching architecture students was proposed, and then the effectiveness of its application was tested in the context of sustainable design skills and the impact of the method used on the sense of responsibility for the actions taken.

5. Aims and Scope

The article presents the methodology and results of the implementation of NEB assumptions and the related principles of sustainable design as part of the Environmentally Friendly Dwelling Architecture course implemented at the second degree of studies at the Faculty of Architecture, Wrocław University of Science and Technology. The aim of the research is to demonstrate the possibility of implementing the EGD and NEB principles using the methods of sustainable design, the impact of their application on design skills, taking into account the challenges of the climate crisis, the impact on the increase in environmental awareness, and the assessment of the results and usefulness of such an approach in the educational process. The article indicates the following principles and methods of education developed on the basis of the NEB guidelines and the theoretical and practical knowledge of the author:

• educational principle of four-stage works on the project;

• principles of sustainable architecture;

• principles of education referring to the principles implemented at the Bauhaus art school;

• principles deriving from the objectives of the EGD;

• a method of assessing the effectiveness and purposefulness of research;

• the survey method as a didactic and scientific experiment.

The course was carried out in the academic year 2020/2021; it was an elective course, and 15 students (divided into 6 project groups) took part in it.

6. Teaching Method and Scope of the Course

The subject of the course was the design of multi-family residential buildings located in Wakefield, Ontario, Canada, that meet the requirements of sustainable and environmentally friendly construction. There were several plots to choose from, divided into two groups—urban plots and suburban plots. The guidelines for each plot type were as follows:

Urban plots:

The designed space should consist of mutually interpenetrating neighbor spaces with cheap, eco-architecture, made using environmentally friendly technology (e.g., modular).

As part of the architectural concept, the following spaces had to be designed:

• residential—multi-family, with a diversified structure of apartments: M1 (36–46 m²), M2 (72–82 m²), M3 (108–118 m²), M4 (120–130 m²), and M5 (144–154 m²), connected with outdoor, open, or built-up individual or community spaces, with assumed specificity;

• ecological cultivation (permaculture gardens), use and recovery of rainwater, and hobby and service spaces (technical, utility rooms, waste);

• pro-social/community/co-working (e.g., shared kitchens, small gastronomy, studios, multi-functional rooms, community gardens);

• eco-educational (e.g., sensory gardens, permaculture crops);

• recreational (e.g., yoga, fitness, open sports areas);

• office and service (e.g., workplaces, shops);

• Service area (utility room, technical room).

The proposed assumption should include solutions ensuring active and passive energy gains, the largest possible biologically active surface, and the recovery and use of rainwater.

Suburban plots:

The designed space should consist of mutually interpenetrating, complementary spaces:

• experimental, residential: single-family and low-rise multi-family (including intermediate city villas);

• a diversified structure of apartments: M1 (36–46 m²), M2 (72–82 m²), M3 (108–118 m²), M4 (120–130 m²), and M5 (144–154 m²), connected with outdoor, open, or built-up individual or community spaces, with designed specificities: ecological cultivation (permaculture gardens), use and recovery of rainwater, and service spaces (technical room, utility room, waste);

• pro-social/community/co-working (e.g., shared kitchens, small gastronomy, studios, multi-functional rooms, community gardens);

• eco-educational (e.g., forest kindergarten, ecological education center, sensory exhibition space, ecological education park—closed, and a local wild ecosystem, created on the basis of the existing forest and park space, sensory gardens, permaculture crops);

• recreational (e.g., yoga, fitness, outdoor sports areas);

• service area (utility room, technical room).

Other guidelines:

The planned assumptions on both urban and suburban plots were to take into account the following requirements and optional pro-ecological solutions:

• respecting and referring to the local biosphere in the design process;

• preferred use of local, natural materials, taking into account the life cycle of the materials;

• inclusion at the pre-project analysis stage of energy simulation on the urban model, water circulation and retention, zone and sector analysis, and a planting plan;

• conscious design of facilities, taking into account their energy balance and carbon footprint;

• conscious design of the building surroundings, taking into account the area for vegetable gardens and/or box crops;

• conscious design with the choice of renewable energy sources;

• conscious design of retention pools, rainwater collection sites;

• conscious design of composters, waste segregation, and recycling sites;

• conscious design of eco-transport (bicycle shops, carsharing, and electric car charging stations);

• conscious design of permaculture gardens, hives, optional mini-farms, and farms (along with the rooms necessary to handle animals).

Work was carried out in groups of 2–3 students, thanks to which the learning was carried out in a more effective way [48,49], in line with the rules applied in the Bauhaus school [7].

Another principle applied in accordance with the demands of Baukultur, the Bauhaus, and the NEB was the cooperation of students with specialists in many fields. During the course, individual classes in the following weeks were divided into two consecutive parts—the theoretical part, led by a specialist in a given field, and the practical part, during which consultations took place (usually with the specialist from the previous week). Thanks to this, the principles of collective cooperation of many specialists on one topic, combining the theoretical and practical parts [1,6,11], were implemented. The following lectures were carried out, combined with consultations conducted by nine specialists (in brackets are indicated the areas of EGD activities from A to E (Table 2) and the features of sustainable architecture from I to XXVII (Table 2) carried out by a given lecture):

• Energy modeling of the building using SketchUp Pro 2021 and Sefaira software, v. 3.0.0 (A, B/I, III, IV, V).

• Rainwater retention installations (D/XXI, XXIII).

• Home crops (B, C/VI, X-XIV).

• Eco-design (A-E/I-XXVII).

• Eco-housing architecture integrated with ecological education parks in the suburban environment (C, D/X, XIII, XIV, XVI, XXII, XXIII).

• Innovative modular construction (B, D/VI, XIX).

• LCA analysis using Athena Impact Estimator software, v. 5.4 (D/XV, XVI, XVII, XVIII, XX).

• Universal design (B/VII, VIII).

• Greenery as an element of environmentally friendly architecture (B, C, E/VI, X-XIV, XXIII).

• Photovoltaic installations (A, B/II, V, IX).

• CLT wood constructions (D/XVI, XX).

• Modern building structures (D/XIX).

• Futuristic architecture (B/VII, VIII).

Work on the project was carried out in four stages (Table 3):

In order to perform a detailed evaluation of the project, it was proposed to select 12 project indicators divided into 4 groups. Table 4 summarizes the proposed indicators in conjunction with the EGD (from A to E) and principles of sustainable design (from I to XXVII):

The work uses the Research Through Design (RTG) method, which combines the necessary teaching and interdisciplinary research. The RTD method involves the inclusion of design activities in the research process and the use of design to acquire new quality knowledge, including knowledge about sustainable development. By creating prototypes, patterns, sample projects, and unfinished products, it is possible to explore potential opportunities and innovations without large and risky investments [61]. This method also brought beneficial effects when conducting courses on similar subjects [62].

7. Results

On the basis of the completed projects, the values of the sample project indicators obtained in each of the groups were summarized. The summary of the obtained indicators is shown in Table 5.

The best results were obtained for the following indicators: E2 (cooling energy)—average 10.48 kWh/m²y, which means category A; E3 (final energy)—average 52.5 kWh/m²y, which means category A; EN1 (embodied energy)—average 4459.37 MJ/m², which means category A; EN2 (carbon footprint)—average 283.69 kgCO₂eq/m², which means category A; EN5 (vegetable planting)—average 76.2% of yearly demand, which means category A; EN6 (fruit planting)—average 69.3% of yearly demand, which means category A. The worse category B was obtained by the students for the following indicators: E4 (photovoltaics)—average 68.6% of yearly demand, EN3 (gray and rain water)—average 69.3% of demand for flushing toilets and watering garden crops, EN4 (mains water)—average 30.7% for demand for flushing toilets and watering garden crops, and IC1 (DA300)—average 72% of occupied hours with 300 lux illuminance. The worst result was achieved for the E1 index (heating energy)—an average of 30.18 kWh/m²y—which means category C.

All indicators were presented on a radar chart, selected examples of which, together with illustrative visualizations, are presented in Table 6.

Additionally, during the consultations, each group was encouraged to perform comparative analyses of various variants in order to select a more favorable one for the selected design indicator. In addition, the groups had to perform comparative LCA analyzes by comparing different material variants.

8. Course Evaluation

After the end of the course, it was evaluated by means of a questionnaire survey as a didactic and scientific experiment. The aim was to test the effectiveness of the course method and its impact on sustainable design skills and the environmental awareness of the course participants. Moreover, the influence of particular project areas on the possessed skills and the degree of difficulty with their development were examined in detail. The survey included 12 closed questions and one open question; 14 people took part in the survey, which constituted 93% of people participating in the course.

The questions and the results are presented below (Table 7):

The survey showed the usefulness of the presented approach to teaching. All the respondents clearly stated that the course provided them with new knowledge (100%, Question 1), the obtained knowledge would allow them to design in a climate-responsible manner in the future (21% confirmed it and 79% confirmed it strongly, Question 5), and that they would definitely recommend the course to others (93%, Question 12). All respondents agreed (7% confirmed and 93% strongly confirmed, Question 4) that the course addressed the issues of the climate crisis.

Most people (71% strongly confirmed, Question 2) assessed the cooperation (lectures and consultations) with specialists in various fields as valuable, although the assessment of the lectures presented was different: from very good ones related to energy efficiency, rainwater retention, crops, or photovoltaic installations (71% considered that the lecture provided valuable information) to those with lower ratings related to CLT wood, modern structures, or futuristic architecture (only 21% considered that the lecture provided valuable information); lectures on universal design and educational ecological parks were poorly rated (14 and 7%, respectively, Question 3). Additional discussions showed that the lectures that conveyed specific knowledge based on numerical data and calculation methods based on presented formulas and given examples were better assessed. Thanks to this, the knowledge from the lecture could be implemented in course projects.

The course participants received the idea of calculating the design indicators presented on a radar chart very well (93% strongly stated that it was a good idea, while 7% said it was a good idea; Question 8) despite the fact that it required more work from them and involved mastering new skills, often from specializations other than architecture. It should be added that most design courses do not offer such knowledge and do not require precise calculations (based on the author’s interview with the authors of other courses). It was assessed that calculating at least half of the indicators brought a lot of satisfaction and knowledge (average 53%, Question 9), with the most satisfactory being the calculation of energy efficiency indicators (79%), electricity production from PVs (71%), and use of gray and rain water (71%, Question 9). According to the indications of Question 10, these were also easy to calculate indicators (only 36%, 14%, and 0%, respectively, had difficulties in calculating a given indicator), and their significance for the design process was also assessed differently (79%, 50%, 7%, respectively).

Other interesting conclusions show that, for example:

• calculations of energy efficiency were considered important (79%, Question 11), not difficult to calculate (36% had difficulties, Question 10), and satisfactory (79%, Question 9), which suggests their strengthening in the future.

• calculations of the current from PV installations were considered satisfactory (71%, Question 9) and very easy (14.3% had difficulties, Question 10) but not important for everyone (50%, Question 11).

• calculating the embodied carbon footprint was considered the most difficult (64% had difficulties, Question 10) and, at the same time, one of the most important in design (79%, Question 9), which suggests the need to develop tools to support its teaching and calculation.

• calculating the possibility of local food production was assessed as satisfactory by half of the respondents (50%, Question 9) and very easy to perform (0%, Question 10) but relatively irrelevant when designing (7%, Question 11).

9. Conclusions

The work demonstrates the relationship between the historical Bauhaus art school, the Baukultur movement concept derived from it, the assumptions of the NEB, and the assumptions of sustainable design. The method of teaching the design course Environmentally Friendly Housing Architecture has been indicated, as well as the method of evaluating the work performed and the course itself. Certain assumptions, e.g., an innovative approach to design, group work, cooperation with specialists from many fields, learning the practical skills of calculating the proposed design indicators, and striving to improve them, have brought a positive effect. The completed questionnaire survey showed the correctness of the assumptions, methods, and project evaluation criteria used, as well as the high didactic value of the course. The need for additional work in the form of calculating project indicators was well received because it brought a lot of satisfaction and new knowledge. Particularly valuable is the information that the ability to calculate the embodied carbon footprint of a building is a difficult but desirable skill; this was assessed as very important in the design process. This is particularly important because the Committee on Environment, Public Health, and Food Safety has adopted its Report On the New EU Circular Economy Action Plan, where it calls for science-based and binding 2030 EU targets for materials use and consumption footprints, covering the whole lifecycle of each product category placed on the EU market. To this end, they urge the Commission to introduce in 2021 harmonized, comparable, and uniform circularity indicators for material and consumption footprints [63]. Additionally, because the research shows that according to the construction sector, architectural specialization is the most responsible factor for the decarbonization of construction [64], it is necessary to quickly develop a uniform methodology and create appropriate tools that can serve as the basis for the development of teaching plans at architectural universities.

The work uses the aforementioned RTG methodology, thanks to which it is possible to search for optimal building parameters using a digital model in terms of the expected values of design indicators. In a complex and multi-criteria environment, the multi-criteria optimization of designed buildings, carried out in cooperation with many specialists, brought the participants of the course a lot of knowledge and satisfaction, with the buildings designed in an environmentally friendly way.

Taking into account the above assumptions, the positive reception of the course, and the results achieved through optimization of the adopted solutions, the teaching method developed for the needs of the design course Environmentally Friendly Housing Architecture course can be used by other educators.

10. Future Works

In the future, the author intends to devote more time to the modernization of existing buildings, which will correspond to the Renovation Wave program implemented by the European Commission under the EGD. The proposed ‘build less’ approach, maximizing the use and exploitation of existing assets, could enable an 80% reduction in carbon emissions, as opposed to the ‘build smart’ (50% reduction) and ‘build efficient’ (20% reduction) approaches, which are insufficient from the point of view of the strategy to achieve the goal of climate neutrality [65].

Additionally, after the European Commission announces the winners of the NEB competition, the distinguished ideas and projects will be analyzed and implemented.

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Enlarge this image.

Figure 1. Examples of Bauhaus designs: (a) Wagenfeld lamp (photo by I. Sailko, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=17436047, accessed on 24 August 2021); (b) Cesca chair (photo By Holger Ellgaard—own work, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=4575023, accessed on 24 August 2021); (c) Barcelona chair (photo by I. Sailko, CC BY 2.5, https://commons.wikimedia.org/w/index.php?curid=6334832, accessed on 24 August 2021); (d) Dessau school building (photo by Mewes, public domain, via Wikimedia Commons https://commons.wikimedia.org/w/index.php?curid=165180, accessed on 24 August 2021); (e) Haus am Horn House (photo by I. Sailko, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=17433782, accessed on 24 August 2021); (f) Barcelona Pavillion (photo by Hans Peter Schaefer, CC BY-SA 3.0, via Wikimedia Commons https://commons.wikimedia.org/w/index.php?curid=52728, accessed on 24 August 2021).

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