Architecture Portfolio 2020 by Jan Dankmeyer

ARCHITECTURE PORTFOLIO A selection of academic and professional works 2017 - 2020 Jan Dankmeyer 08.2020

INTRO

Ever since I received my first LEGO bricks on a small Danish fairy to the island Samsø, it determined my path of the future. My curious and ambitious character are key drivers to participate in creating the world of tomorrow sustainably.

With my Master’s Thesis, I chose to dig deeper into the topics of environmental psychology and environmental education to design a learning landscape for children that teaches about urban resilience and nurtures sustainable behaviour.

I consider myself a pragmatic designer yet contextually aware, always on the lookout for poetry in space that serves human needs.

My dedication to sports in general and Basketball, in particular, has had a long-lasting effect on my personal development. As a team player, I contribute with precision, persistence and humour, always with a helping hand to bear.

The fascination of buildings and their relationship to public space has always been interesting to me. I firmly believe that architecture that is deeply interwoven in its physical and cultural context has the power to influence behaviour and has a positive impact on society. This is why I strive for human-centred design solutions that enrich the lives of people from the urban scale up to the architectural detail.

JAN DANKMEYER

EDUCATION

German, 06.04.1993 Mail jan.dankmeyer@gmx.de Phone +46 79-339 56 81 LinkedIn jandankmeyer Address Norra Ågatan 3, lght 1305 416 49 Gothenburg, Sweden

Intro

M.Sc. Architecture and Planning Beyond Sustainability Chalmers University of Technology, Gothenburg, Sweden 09/2018 - 06/2020 B.Sc. in Architecture Bochum University of Applied Sciences, Bochum, Germany 09/2012 - 08/2017

As I am positive and open-minded by nature, I believe in the collaborative design process to turn the negative impacts of the building industry into a positive one.

WORK Junior Design Architect RKW Architektur +, Düsseldorf, Germany 09/2017 - 08/2018 Student Assistant in Construction Planning ACMS Architekten GmbH, Wuppertal, Germany 04/2017 - 09/2017 Student Assistant in Construction Planning a|sh - sander.hofrichter architekten GmbH, Düsseldorf, Germany 09/2015 - 10/2016

PLAYABLE ADAPTIVITY

Master’s Thesis in Urban Challenges Studio Chalmers University of Technology 02/2020 - 06/2020

4 40 JOHNSON PLUS VARIOWOHNEN RKW Architektur + 01/2018 - 07/2018

STRAIGHT TO HILL

Sustainable Building Competition Chalmers University of Technology 09/2019 - 01/2020

KRAFTBADET

Architectural Heritage & Transformation Chalmers University of Technology 02/2019 - 06/2019

STADTHAUS COZWO

Bachelor’s Thesis Bochum University of Applied Sciences 04/2017 - 08/2017

ACMS_Architekten GmbH 04/2017 - 09/2017

HAMNMAGASINET405

Complete Portfolio:

EUROPAN 15 Competition 06/2019 - 07/2019

https://issuu.com/jan. dankmeyer

SELECTED WORK 2017 - 2020

Table of content

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The Water Road

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The Water Square

The Wetland

The Rain Roof

PLAYABLE ADAPTIVITY How to Educate the Designers of Tomorrow for a Resilient Urban Future Project location Gothenburg, Sweden Project year 02/2020 - 06/2020 Course, direction Master’s Thesis, Urban Challenges Tutors Examiner: Emílio Brandão Supervisor: Joaquim Tarrasó, Marco Adelfio Keywords children’s perspective, climate adaptivity, urban resilience, designing for children, environmental education , environmental psychology, water sensitive urban design Software Archicad, Rhino, Photoshop, Illustrator 1

Axonometry

Playable Adaptivity

Master’s Thesis online exhibition and complete book: https://projects.arch.chalmers. se/jan-niklas-dankmeyer/

Scale 1:750

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Green structures - existing Green structures - new Blue structures Pedestrian area Soft pavement for children Traffic road Tram lines

Connectio

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Sustainable Urban Water Treatment

Water States of

Infrastructure

Movem

ent

Plac

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Pla ns

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Cycle

Plantation

Wate r

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02/2020 - 06/2020

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Master’s Thesis

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Defines the aim and fields of research while limiting the work to that which it includes

Delimitation diagram

This Master’s Thesis focuses on the children’s perspectives within the urban fabric by investigating how child-responsive spatial design can be combined with environmental education. Correspondingly, the concept of environmental psychology and built environment education will be introduced to combine pedagogy and architecture. Thereby, the concept of play needs

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The rapid process of urbanisation combined with climate change threatens children to grow up on an inhabitable planet. For many decades, urban planning and architecture have been giving low priorities to children’s perspective in the built environment. Since children are the most unbiased part of society, yet the most vulnerable one in terms of climate change impacts, the urge to integrate them has to be seen as an inherent part of urban planning.

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Children in our cities will account for 60% of urban dwellers by 2030 (United Nations, 2016). There is a necessity to educate an ever more increasing urbanised society about the complexity of Earth’s natural systems in order to achieve environmental and social resilience.

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Can playgrounds be integrated into everyday urban life as a tool to educate children on climate resilience?

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Children’s Perspective

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Haga Station Feskekörka Pedestrian Bridge Pier (The Red Ribbon)

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Social Inclusion

The Rain Roof Amphitheatre

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Connection to Nature

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Swale Biotope/Wetland Street crossing ditch Open channel Bioretention Multifunctional space Detention Pond Infiltration Trench

Environmental Education

Urban

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to be integrated into everyday urban life in order to promote outdoor activity and to nurture children’s personal development. The context of the design proposal is Gothenburg, Sweden, which will be facing significant climate change challenges, due to flooding caused by both the rise of sea water level and increase of precipitation. Conformable to environmental education, water sensitive design is introduced as a method to couple context-based urban challenges with environmental education as a pedagogical and playful element to educate about urban resilience. In compliance with the research-for-design method, this work aims to create a spatial interface for children where the experience of space and movement in relation to climate adaptivity breaks ground for a new perspective on public spaces. The design outcome of this Master’s Thesis strives to contribute to environmental awareness and urban resilience through child-responsive design.

Philosopahy of Sustainability - Fantasy, imagination - Recognising essence Intervention in Urban Fabric

Understanding of How Important the Earth Is

Children’s Perspective

Environmentalfriendly Behaviour

Influence Social Structure

Sustainable Technology - Factual information - Knowing about

“Sustainable technologies must be combined with a philosophy of sustainability, a thorough understanding of how important the Earth is to us, resulting finally in a new architecture and a new visual language.” 3

1 2 3

View Diagram Anne Taylor (2009, p. 364)

Playable Adaptivity

Built Interventions as Pedagogical Interface According to the theory of environmental psychology, a high level of environmental awareness leads to environmentally friendly behaviour (Schneider, 2019). Apart from personal measures, it requires structural measures which focus on architecture and urban planning to encourage environmental behaviour. Schneider (2019) argues that “interventions in the built environment can impact the social structure, and vice versa, changes to social structures can impact the built environment”. Interventions

in the urban fabric that incorporate the child’s perspective and function as a pedagogical platform to increase environmental awareness can be a strategy with long-term impacts on a child’s personal development. Schneider (2019) states that these spatial interventions will be more successful the more specifically and personally they are designed. In this sense, children who are eager to explore and learn about their environment become the recipients “who are willing to receive and process the message” (Schneider, 2019).

“The Wetland” How to influence the social structure through spatial interventions

1 Child-responsive urban planning

Sustainable Storm-water Management

Learning Partnerships

Theory-based design strategies

Multi-funtional Topography

Structured & Unstructured Play

Safety

Built Environment Education

Accessibility

Blurred Lines

Consider the Local Climate

Consider the Parent’s

role

Combine Water Management and Play

Showcase the Use of Water

Consider all Kinds of Senses Create Movements Shape Symbolism

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View Diagram

Master’s Thesis

02/2020 - 06/2020

Knowledge was retrieved from the three main fields of research; children’s perspective, environmental education and water sensitive design. Based on the research findings, several theory-based design strategies were developed in order to build up a framework for the design proposal. The aim is to link theories from different research fields and to create synergies among them through spatial design. Based on the theoretical research for this thesis, generic and site-specific principles were developed to create a learning landscape for children. The design principles are divided into generic and site-specific strategies. The generic strategies focus on the children’s perspectives and environmental education and offer the potential to be translated and up-scaled into various contexts and locations in the world. The site-specific strategies result from the exploration of generic information. In this case, the sitespecific design principles connect to sustainable and resilient urban water treatment which is Gothenburg’s urban challenge. In different contexts, other context-based challenges could become a tool for educating children about the environment, and thereby support social and environmental resilience.

“The Water Square” Interdependencies of design strategies

Transitional Elements

Natural Elements

Movement

Wide Open Spaces Age appropriate division

Zoning

Nature-inspired Topography

Visibility of all areas (Supervision)

Surface material Biodiversity Visual Experiences

High Vegetation Areas

Foster Stewardship

Stimuli

Well-being

Tactile Experiences

Mild Risks

The Learning Landscape

Agricultural Elements

Multi-sensory Elements

Physical Challenges

Community Garden

Group spaces

Workshops

Exhibitions

Furniture to suggest pattern of use

Amphitheatres

Learning Facilities for Children

Develop learning partnerships

Break Boundaries between inside and outside

Covered Spaces

External resources from the environment of local climate

Built Elements

Cultural Elements

Figure 11

The Learning Landscape Synergies between Functions and Activities

Categories and sub-categpries retrieved from Taylor (2009) and Hudson and White (2020)

“The ideal educational environment is a carefully designed physical location composed of natural, built, and cultural parts that work together to accommodate active learning across body, mind, and spirit.”2 The Importance of Natural Environments Hills, canyons, forests, lakes, meadows, lakes and fields were the natural habitat in which children used to play. According to Loud (2006 as cited in Kopec, 2018) these natural settings “facilitate experimental and experiential learning that teaches valuable problem-solving skills.” They provide a greater complexity and thereby better support the development of motor and navigation skills (Fjørtoft, 2004 as cited in 1

Diagram

Taylor (2009, p. 31)

Playable Adaptivity

Kopec, 2018). Kopec (2018) argues that a rich provision of nature-inspired topography and vegetation growth is one key factor for welldesigned outdoor spaces. Natural elements expose children to visual, auditory, tactile, and olfactory stimuli that support the development of creativity, intellect, and social skills (Kopec, 2018). Furthermore, many studies have shown that a well-established connection to nature can lead to improvements for children in regard to concentration issues, such as ADHD (attention deficit hyperactivity disorder), or cognitive fatigue (Hudson and White, 2020). Hudson and White point out that the outdoor environment is “an accessible and inexpensive space”. However, to provide freedom of choice, it is crucial to break down the boundaries between interior learning environments and

outdoor areas. If learning environments are connected to the outdoors, learners can be more creative, allowing them to construct, build and adapt the space to their needs (Hudson and White, 2020). The external landscape also offers opportunities for defined group spaces, imaginative walks, physical challenges, natural habitats, and amphitheatres for class gatherings or performances (Hudson and White, 2020). In this regard, Taylor (2009) summarises that child play, ambient features, biotic and spatial elements, outdoor classrooms, and therapeutic/ access areas are the best features for childhood playscapes.

The learning landscape: Synergies between functions and activities

Playgrounds

Green structures

Cloudburst routes

Preschools

Blue structures

Project site

Schools

Impervious surfaces

Area projected to be flooded

“Climate consideration and a sustainable lifestyle will become clearly defined elements in the day-to-day lives of the next generation of Gothenburg inhabitants. It is vital that children and young people acquire knowledge at an early stage about human impact on climate and how they can live in a good, climate-smart way.”2 Project Site: Pusterviksplatsen in Central Gothenburg

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Overview map central Gothenburg Statement by the City of Gothenburg

Master’s Thesis

02/2020 - 06/2020

Central Gothenburg offers opportunities to strategically implement resilient solutions for water treatment as a method to educate children playfully about climate change impacts. Thus, to apply the research findings in the form of an architectural project, Pusterviksplatsen, a neglected public square in Central Gothenburg has been identified as an appropriate site. On behalf of Göteborgs Krettslopp och Vatten (the local authority for water treatment) and Stadsbyggnadkontoret (the local building authority), Sweco has conducted a cloudburst

Projected flood scenario Climate Programme for Gothenburg (2014, p. 34)

modelling to two-dimensionally illustrate the accumulation of water and run-off routes within Gothenburg in the case of a 100-year-event and a 500-year-event. In both scenarios, the results for Pusterviksplatsen show that stormwater will flow towards Rosenkanalen, accumulating at depths up to 0,5 meters partially on-site, on the adjacent Nya Allén, and in the streets of Haga due to the topography of the nearby Linné area. This will disturb the area’s access and infrastructure, and, in worst-case scenarios, could pose risks to human health and life.

Scale 1:5000

1 2-3 4-5

Graphical Manifesto Exploration and application of design principles Atmosphere under the rain

Playable Adaptivity

Flows and Urban Interrelations

Predicted 100-year-rain-event

Topography Development

Predicted High Flood Scenario - 2100

Shapes of Nature vs “Human Thought”

Application of Water Sensitive Urban Design

Distribution of Activities

Master’s Thesis

02/2020 - 06/2020

Rainwater Harvesting

Bioretention

Multifunctional Space

Roof Retention

Infiltration Trench / Zone

Detention Pond - dry

Open Channel

Swale

Detention Pond - wet

Biotope

Delay of water flow dimensioned volume and less Delay of water flow - can handle cloudbursts Derivation of surface water - dimensioned volume and less Derivation of surface water - can handle cloudbursts

Edge Conditions

Street Crossing With Ditch

Permeable Pavement

Water Flow Carrying Road

Small to medium purification effect Major purification effect Ecological benefits

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Toolbox â&#x20AC;&#x153;Pedagogical Water Sensitive Designâ&#x20AC;? Perspective Section a-a

Playable Adaptivity

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1 Green structures - existing Green structures - new Blue structures Pedestrian area Soft pavement for children Traffic road Tram lines

a b c d e f g h

Swale Biotope/Wetland Street crossing ditch Open channel Bioretention Multifunctional space Detention Pond Infiltration Trench

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The Rain Roof Amphitheatre

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Haga Station FeskekĂśrka Pedestrian Bridge Pier (The Red Ribbon)

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Site plan Section b-b

Masterâ&#x20AC;&#x2122;s Thesis

02/2020 - 06/2020

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STRAIGHT TO HILL Mix-used Timber High-rise as Public Connector Project location Gothenburg, Sweden

Project site Located in the old harbour area, Lilla Bommen is being transformed into a central business area. The project site is located adjacent to the new bridge connecting central Gothenburg and Hisingen.

Project year 09/2019 - 01/2020 Collaboration Frida Forkman & Shuyun Hue Courses Sustainable Building Competition - 3rd prize Building Design Lab Tutors Lasse Lind, 3XN/GXN John Helmfridsson, Chalmers + Wingårdhs Client Vasakronan Keywords Circular economy, behaviour design, timber construction, low-tech, up-cycling Software Archicad, Rhino, Grasshopper, Photoshop, Illustrator

Straight to Hill

View

Competition brief The task was to design an 18.000m2 mixed-used timber High-rise. In close collaboration with GXN, circular design and behaviour design were further explored, as they were central aspects of the design process. In addition to the three given focus areas “timber construction”, “energy and indoor climate” and “up-cycling”, two more focus areas were to be developed. The course “Building Design Lab” provided the tools to optimise the facade of the design proposal according to energy consumption, daylight factor and thermal comfort. Concept The design strategy emerged from a twofold approach. Due to the lack of green spaces in the area and the new bridge being an enormous spatial element, the idea was to design the

building as a public landscape connecting the bridge level with the level of the waterfront. Furthermore, responding to the present development of ever more high-tech solutions in architecture, this projects aims for a low-tech but yet high-intelligence approach. In particular, wind and natural ventilation became the main focus of the design proposal. Challenges The main focus was on how to define and address the focus areas in terms of sustainability and combine all of them in a thoroughly designed building. Due to time constraints, not all focus area could be developed in enough detail. Outcome We were named third-placed and the jury panel consisting of Vasakronan, City of Gothenburg, GXN and Chalmers praised our effort in researching wind simulations and developing the design proposal according to the low-tech approach. The landscape was appreciated for its integration in the urban environment, as it provides human scale in the form of a playful, soft and unpredictable park.

“On the Bridge”

STRATEGY 1 STRATEGY 1 choices of materials, choices of materials, e.g: e.g:

STRATEGY 2 spatial decisions, e.g:

STRATEGY 1 choices of materials,

Given Focus Areas

INSULATION

STRATEGY 2 spatial decisions, e.g: ORIENTATION

e.g: INSULATION

INSULATION

CLADDING

ATTACHED GREEN

Timber construction

Up-cycling

NATURAL VENTILATION

CLADDING

THERMAL MASSING

Energy and indoor climate

CLADDING

ORIENTATION

NATURAL VENTILATION

SHADING

ATTACHED GREEN

SHADING SHADING

REFLECTION OF LIGHT

THERMAL THERMAL MASSING

REFLECTION

REFLECTION OF LIGHT OF LIGHT

MASSING

Connecting landscape

ORIENTATION

NATURAL VENTILATION

ATTACHED GREEN

Created by Flatart from the Noun Project

Created by Denis Devyatov from the Noun Project

STRATEGY 2 spatial decisions, e.g:

Low-tech design

B A

GSEducationalVersion

Stepping “aside” for Nature

GSEducationalVersion

Elevation

Corresponding to pace scales

Northwest

GSEducationalVersion

Sustainable Building Competition

Shelter from noise and pollution

Sheltered Views

Scale 1:500

GSEducationalVersion

09/2019 - 01/2020

Prevailing Wind Direction

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GSEducationalVersion

1 a b c d e f g h

1 2-4

Straight to Hill

Floor plan Design process

Promenade level

Entrance gallery Entrance hall Cafeteria Exhibitions and events Supermarket Commercial/shop Changing and restroom Gรถtaalspool Nature paths

Scale 1:500

1 2

Elevation Section

Sustainable Building Competition

Northeast a-a

09/2019 - 01/2020

Scales 1:500

Wind analysis Due to its location by the water the building and its incorporated landscape are exposed mainly to the wind coming from the west coast. We used a wind tunnel to simulate how the wind would behave on site in order to shape the landscape and to create sheltered areas in the park for people to stay and to enjoy the view on the water. A canopy above the landscape structure diminishes the â&#x20AC;&#x153;downdraught effectâ&#x20AC;?, which prevents inducing the phenomena of a vortex at the bottom of the building, and improves the sojourn quality significantly (see sketch). 3

SUMMER DAY

WINTER NIGHT

WINTER DAY

SUMMER NIGHT

SUMMER DAY

Winter night: Heat release through thermal mass

Winter day: Heat Recovery System + Floor heating

Summer night: Night ventilation

Summer day: Cross and stack ventilation

Natural ventilation concept The positioning of the building enables to incorporate natural ventilation. The building relies on a mixed mode system that makes use of a combination of cross and stack ventilation and a heat recovery system during the winter months (see axonometry on next page). 1 2 3

Straight to Hill

Inside the wind tunnel Measuring the velocity The canopy protecting the lower areas from the downdraught effect 18

WING ROOF The Wing Roof located above the thermal flue top opening uses the Venturi effect to accelerate and further induce exhaust airflow in the thermal flue

NATURAL VENTILATION The natural ventilation system relies on cross-ventilation at each floor induced by stack effect in the double skin facade which acts as a thermal flue.

“RIGH” HOUSES Circulation as shared space

Prevailing Wind direction from South West.

DOUBLE-SKIN FACADE The Double-skin facade is not only a technical addition but also provides stairs for circulating encouraging movement and STRATEGY 1 relation between floors. choices of materials, e.g:

INSULATION

CLADDING

ORIENTATION

STRATEGY 2 spatial decisions, e.g:

ORIENTATION

NATURAL VENTILATION

ATTACHED GREEN

SHADING

THERMAL MASSING

REFLECTION OF LIGHT

OFFICES Every third floor the design provides a communicative floor with a larger kitchen, meeting rooms and recreation spaces.

PASSIVE SHADING The facade is shaped according to the passive shading concept and at the same time allows for views on the water.

CO-OFFICE SPACES

Due to its positioning, the building allows harvesting wind from the prevailing wind direction, solar energy and at the same time acts as noise barrier from the bridge

GALLERY

COMMERCIAL

CAFETERIA / BAR GALLERY / EVENTS

Axonometry

Sustainable Building Competition

Scale 1:1000

09/2019 - 01/2020

GSEducationalVersion

Facade Concept

In compliance with the concept of low-tech - high intelligence, we created a facade that enables passive shading while providing sufficient daylight throughout the day. The geometry of the passive shading elements were designed to protect from the sun during the summer and harvest solar energy during the winter by minimising the energy demands. The strict structure of the facade reinforces the contrast as a floating rational volume over the soft and playful landscape.

Facade Optimisation with Grasshopper In the course “Building Design Lab” the facade of the office part was to be optimised regarding energy usage, and thermal and visual comfort. During the optimisation process we explored the effect of orientation, zone geometries and façade. To do so we had to pick several representative rooms. For the simulations we applied several plugg-ins in the Grasshopper environment. Ready-to-go templates were provided by the course. The “Design Explorer”, an online interface that enables to visualize and filter groups of iterations from parametric authoriting applications, helped to decide the optimised depth of the shading elements. The optimisation process resulted in different depths of the facade, depending on the orientation of the representative room.

1 2 3 4 Straight to Hill

Elevation Analysis of sun hours Distribution of daylight in a representative room Visualised design iterations

Southwest

Scale 1:500

555

Created by Alan Davis from the Noun Project

3 245

Created by Aenne Brielmann from the Noun Project

Created by Natasja Buer Toldam from the Noun Project

anhsirk yb detaerC tcejorP nuoN eht morf

Created by Adrien Coquet from the Noun Project

555

Created by Stepan Voevodin from the Noun Project

Floor Composition

Wall Element Composition

Rammed earth floor, floor heating Seperation layer Sound insulation layer Bonded chipping CLT slab Substructure Sound absorbation insulation Perforated wood cladding

Pine cladding Battens, counter battens Facade membrane Timber frame structure, thermal insulation Cladding, vapour barrier Plaster boards Installation layer, thermal insulation Clay boards finnish

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Detailed Section View â&#x20AC;&#x153;The Hillâ&#x20AC;?

Sustainable Building Competition

Scale 1:25

09/2019 - 01/2020

KRAFTBADET Gröna vägen i Forsåker Project location Mölndal, Sweden

Context

Project year 02/2019 - 06/2019 Collaboration Vera Matsdotter Course Architectural Heritage and Transformation Tutors Kia Bengtsson Ekström Oscar Carlsson

Kraftbadet

View

Task Transformation of an old water power plant into a new function.

Software Archicad, Photoshop, Illustrator, Cinema 4D

The site is characterised by the presence of water and decay. An old rivers stream runs next to the old water power plant, which has been demolished in half and is decaying fast. The Forsåker area is planned to become a new mix-used district with housing and workplaces located only 8 minutes by tram to central Gothenburg.

Concept The proposal for the old water power plant is a public bath house combined with hydroponic

farming, a food court, and a plant shelter. The idea is to introduce a programme that creates synergies and supports multi-functionality. Sustainable and salvaged materials are an important cornerstone of the design proposal. Rammed earth, clay plaster and timber have been explored in relation to their functionality in a bath house. We aimed to create a warm atmosphere while embracing the industrial traces. Challenges We intended to challenge the bath house typology in terms of both social and ecological sustainability. For us it was crucial for the project to entail a multi-functional programme beyond the bathing function. This added more complexity by solving different flows of both people as well as air, energy, and water. Result Gert Wingårdh was one of our critics on our presentation. We were complimented on the complex programme and on a high level of detailing and materiality. Regarding our team effort he stated that “in this project it is clear that 1+1=3.”

“The Green Way(ve)”

Social Sustainability Norm-innovative approach to the design. A public bath that provides functions which enhance social sustainability and target a diverse groups in society: children, elderly, young, middle age, singles or families.

Circular Economy The building design and functions supports circular economy in terms of material re-use, energy, water & air flows.

Roof Garden

Around the Clock The new functions within the building should activate the Forsåker area around the clock: during all seasons, days, nights and on weekends.

Hydroponic Greenhouse

Gives access to the roof, creating a public partly glazed terraces for yoga and workshops overviewing the Forsåker area!

Connects back to the historical use of water as a source for production and supports the local landmark Gunnebo Slott & Trädgårdar.

Public Bath

Power Plant Café

- creating a place for recreation, rehabilitation and retreat! - swim next to the stream - a public infinity pool! - the water is filtered from the river stream - a cold-bath in the winter or an ice-skating rink

Axonometry

Architectural Heritage and Transformation

- wintergarden with native plants and trees - food and beverage with ingredients from the greenhouse - a place for “den kaffesugna”, nature lover, lunch escaper/out-eater or the night-owl!

Programm and additions

02/2019 - 06/2019

Scale 1:750

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Building 14A

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Building 14B

Building 13

GSEducationalVersion

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Entrance pizza shelter Entrance bath Staircase to roof terrace Water Slide Net Natural swimming pond River stream

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Photovolactic Solar Glass Facade

filtration + water reuse

wa t

transformation + retrofit

Transition to Circular Flows Supporting the zero waste concept and making use of synergies between the different functions.

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Kraftbadet

Floor plan Diagram

Entrance level Supporting technical systems

Scale 1:200

GSEducationalVersion

2 GSEducationalVersion

1 2

Section a-a Section b-b

Architectural Heritage and Transformation

Scale 1:200

02/2019 - 06/2019

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Sauna with garden Filters and technical facilities Swimming pool Hot pool Steam pool Changing rooms Elevator to roof terrace Bar and pizza oven Outdoor bar Ruin garden Kitchen facilities

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GSEducationalVersion

1 2 3

Kraftbadet

Floor plan View Section c-c

Level 0 Steam pool atmosphere Steam pool

Scale 1:200 Scale 1:75

Entrance changing area

Clay plaster -green pigmented

Clay plaster -natural

Up-cycled timber block flooring

Alusid tiles (made from 98% recycled materials)

Stainless industrial metal sheets

Plywood panels

Rammed Earth

Resource Salvation - Terrazzo with (45%) re-cycled concrete mixed with old bricks, glass or marble pieces (developed by Lendager group and Skanska). - Alusid Tiles made from 98% recycled materials will be used in pools and in the showers/wet areas. - Wood for furniture and flooring comes from upcycled wood, otherwise sorted and considered as ‘waste’ - Prefabricated rammed earth wall elements, panels and clay plaster are used for the interior additions. Clay i retrieved (considered waste) from the Västlänken construction in Gothenburg

1 2

View Floor plan

Architectural Heritage and Transformation

Bathe in the ruin space Changing rooms - materiality

02/2019 - 06/2019

Scale 1:75

GSEducationalVersion

1:50

3 GSEducationalVersion

1 2 3

Kraftbadet

View Axonometry Axonometry

Entrance pizza/power/plant Turbine traces and tree transplant Ruin Garden indoor/outdoor spaces

Scale 1:100 Scale 1:100

KRAFTBADET

GSEducationalVersion

1 2

North elevation South elevation

Architectural Heritage and Transformation

Scale 1:200

02/2019 - 06/2019

1 2

Kraftbadet

Detailed Section Detailed Elevation

Scale 1:20

GSEducationalVersion

Timber-frame glass roof construction, triple glazing, photovolactic solar glass facade (20% opacity)

Bended metal sheet and roof gutter

Mineral insulation with partial wooden block for attachment of roof gutter

Wooden covering, 150mm x 40mm

Timber-frame construction triple glazing, photovolactic solar glass facade (20% opacity)

New floor construction: parquet floor on two layers of timber subconstruction (900mm x 45mm), vapour barrier, condensed gravel insulation, vapour barrier, existing reinforced concrete

Bended metal sheet for off running water

Existing concrete attic block, if necessary replaced partially by new casted concrete

Detail roof addition

Architectural Heritage and Transformation

Scale 1:5

02/2019 - 06/2019

JOHNSON PLUS Extension Kunsthalle Bielefeld Project location Bielefeld, Germany Project year 04/2017 - 08/2017 Course Bachelor’s Thesis Tutor André Habermann Software Archicad, Photoshop, Illustrator, Cinema 4D

Context “Kunsthalle Bielefeld“ was designed by Philip Johnson in 1968 and immediately turned into the town‘s landmark. It is a cubic building, 30 meters in length. Its characteristic architecture results from flowing spaces marked by distinctive walls which also appear as design elements on the outside/façade of the building. The upper floor is completely closed and causes the building to bear its striking resemblance to a sculpture. The art gallery is considered one of the most prestigious museums for classical art in Germany due to its flowing spaces and the versatile use of natural and artificial light. Task The space provided within the museum is not sufficient anymore. Therefore, the need for more flexibility are urging. The task was to design

Johnson PLUS

View

an extension to the Kunsthalle that provides opportunities for exhibitions to also encompass contemporary art such as video installations and performances. Concept “Kunsthalle Bielefeld“ and the related sculpture park are important components of the public perception of the urban space of Bielefeld. This potential was internalised and then assigned to the design of the extension building of the art gallery as well. By doing so, the art gallery will be seen as part of the sculpture park. The art gallery and its extension buildings works as a coexisting ensemble integrated within the park landscape. Challanges The decision making regarding the architecture of the extension required a sensible handling as “Kunsthalle Bielefeld“ and its sculpture park impose highly challenging surroundings. Reflection My work was complemented to be the result of an excellent analysis of the context and carefully executed architectural design. I was given a top grade.

“Johnson + extension”

g d f

a b c d

Main entrance Café Seminars “Mauerbar”

e f g h

Exhibition Sculpture yard Medieval wall Delivery

1. Demolition of the existing buildings.

2. Addition of two new volumes.

3. Displacement of the bodies to secure view connections.

4. Adjustment of the proportions related to the urban context.

5. Underground connection between the new volumes and the Kunsthalle.

6. Atriums secure natural light in the basement.

7. Existing landscape design.

8. Extension of the sculpture park and integration of the new buildings.

Bachelor’s Thesis

Floor plan

Entrance level

Scale 1:500

04/2017 - 08/2017

New Existing

a b c d

Library Workshop Multi-space “Mauerbar”

e f g h

Exhibition Sculpture yard Shop Auditorium

4 c

h e

1 2 3 4 Johnson PLUS

Elevation Section Floor plan View

Southeast a-a Basement “Mauerbar”

Scales 1:500

New Existing

GSEducationalVersion GSEducationalVersion GSEducationalVersion

The Facade 3

1 2 3 4

Bachelor’s Thesis

Detailed section and elevation Impressions from section model Facade development Materiality of existing and new ornament facade

To strengthen the shared identity of “Kunsthalle” and the proposed extension, coloured exposed concrete for the new façades were chosen. The smaller cube which comprises administration and seminars works with a clean exposed concrete facade and a grid pattern of windows. The larger cube receives an ornament facade of prefabricated concrete elements referring to Bielefeld’s past as a stronghold for linen production. Thus each of the three bodies of the ensemble has its individual outward appearance, nevertheless the selection of material and colour causes a collective but versatile appearance.

Scale 1:100

04/2017 - 08/2017

HAMNMAGASINET 405 Centre for Circular & Collaborative Consumption

“The Hang Bar” Transformation and extension of the old machine room of the old crane into a public event and exhibition space.

“Hamnmagasinet 405 REturns” The old warehouse is transformed into a hub for reuse, recycled goods and collaborative trade.

“Live Small - Share Big” A proposal for intergenerational housing units. Modular construction made from existing shipping containers .

work/meet/share fika/swap/borrow/trade

Competition Theme Three core concepts: resources, mobility and equity as they are connected to the theme “The Productive City”.

Project location Helsingborg, Sweden

Competition Brief The competition task comprises the transformation of an old warehouse building and its surrounding plot, as well as a crane and its engine room. The assignment is to re-use and re-purpose the warehouse and crane engine room into a productive meeting place in the city, while adding building volumes to accommodate public activities and housing units within the project site.

Project year 06/2019 - 07/2019 Project type EUROPAN 15 Competition Collaboration Vera Matsdotter Client Helsingborg Municipality Software Archicad, Photoshop, Illustrator, Cinema 4D

Axonometry

Hamnmagasinet

405

Scale 1:750

Concept This proposal focuses mainly on resources, which are inextricably linked to equity and mobility.

make/repair/re-invent

In combining consumption, production and exhibition under one roof open to the public, the design creates a space where people can meet, get involved, receive education and become inspired to make sustainable lifestyle choices. Challenges The limited amount of time for the competition being 5 weeks. In terms of the site, the raising of the quay became challenging for the existing warehouse structure being “buried”. Result Studying the winning proposal (with many similarities in terms of program) the learning outcome was that more visualisations are to be preferred.

New Existing

The blue and green harbour landscape The raising of quay is seen as an opportunity to create open and green stormwater channels in different shapes around the site. This new water grid will protect the site from heavy rainfall as well as adding recreational value. Green Roofs on the Housing and Kranens outdoor grym area offers possibility for additional stormwater management.

Kontorsmagasinet L2 Mötesmagasinet L 0-2

Möbelmagasinet L1

Kontorsmagasinet L2

Fixarmagasinet L1

+ Klädmagasinet L0

Materialmagasinet L 0-1

Resternas café L 0-1

1 2 3

View View Section

EUROPAN 15

06/2019 - 07/2019

“Resilient harbour landscape” “Inside Möbelmagasinet” Raised quay and stormwater strategy

Matmagasinet L0

Scale 1:300

2 3↓

+3,4

delivery/loading

Recycling station

+3,4 Klädmagasinet

Exhibition space

Materialmagasinet

GSEducationalVersion

Resternas café

+3,3

Matmagasinet

+2,3 Mötesmagasinet

GSEducationalVersion

+3,3

GSEducationalVersion

+2,3 Entrance plaza

1 2 3

Section Elevation Floor plan

Hamnmagasinet

405

a-a Southwest Entrance level

Scales 1:300

New Existing

GSEducationalVersion

Intergenerational Living GSEducationalVersion

Cities and local authorities are continually faced with the challenge of providing enough housing for young people pursuing education. Another large group in need of housing is the senior population. Therefore, the proposal is to introduce intergenerational living in Oceanhamnen: to “live small and share big”. Modular Construction Freight container room modules open up new possibilities in the housing market in terms of providing flexibility and the ability to react efficiently and sustainably to the market’s demands. Additionally, modular construction and prefabrication make it possible to guarantee building cost security and provide high quality architecture at the same time. The housing units should be designed to be relocated and reused in the future.

GSEducationalVersion

1 2 3 4

View Modules Floor plan Elevation

EUROPAN 15

06/2019 - 07/2019

“Live small - share big” Apartment types Level 1 - Intergenerational living Southeast

Scale 1:300 Scale 1:500 Scale 1:400

New Existing

STADTHAUS COZWO Urban Co-Working and Co-living Project location Düsseldorf, Germany Project year 01/2018 - 07/2018 Architect RKW Architektur + Team Barbara Possinke, Ursula Markowitz, Eike Otto Client Stadtwerke Düsseldorf (Local Energy Supplier) Collaboration kaufmann zimmerei und tischlerei gmbh, Austria merz kley partner GmbH, Austria Software Autocad, Photoshop, Illustrator

Stadthaus

Street view

Overview The project was born out of a business idea to expand the service portfolio of the local energy supplier “Stadtwerke Düsseldorf ”. In close collaboration with RKW, the project was further developed, intending to react to the increasing demand for spaces for co-working and Cohousing. The building consists of a concrete skeleton for the co-working areas including co-housing units constructed of prefabricated timber modules. As an energy supplier, the client developed a specific energy system, comprising district heating, heat pump, solar chimney, heat recovery system and photovoltaic panels.

Knowledge acquired I gained new knowledge about sustainable energy systems and the construction of prefabricated timber modules. An exciting experience was to visit the manufacturer of the timber modules in Austria and to learn about technical solutions regarding fire regulations. Designing an innovative building regarding functions and building materials, as well as dealing with the building authority brought up a lot of interesting discussions and resulted in a very enriching process.

Role I joined this project in the early design phase, and I was responsible for finalising the design according to the demands of the client and the local building authority. In particular, I was in charge to develop the concept of the facade design. The drawings shown are samples of my contribution if not marked otherwise.

Rendering: Ponnie Images

OfenKombi

Küchenzeile

Garderobenschrank

Wandabwicklung A - A

Boden- und Deckenbeläge aus Holz Wohnungstrennwände: Schallschutzanforderung R'w ≥ 53 dB Brandschutzanforderung F90 T30-RS R'w ≥ 37 dB

Wohnzimmertisch

Büro Düsseldorf Tersteegenstraße 30 Bett 40474 Düsseldorf T +49 (0)211 4367-0 info@rkwmail.de www.rkw.plus

Balkone aus Betonfertigteilen auf Massivholzscheiben (accoya modifiziert) aufgelagert Trittschallschutzanforderung Balkone L'n,w ≤ 58 dB

Oberfläche Decke Module aus Holz

Außenwand Lärmpegelbereich III Maßgeblicher Außenlärmpegel La = 65 dB Schallschutzanforderung R'w ≥ 35 dB

Bodenbelag Module: 3-Schicht-Parkett

Glasgeländer

Schreibtisch, Oberfläche Balkone aus Holz (accoya modfiziert)

Sofa

Glasgeländer

Rhode Kellermann Wawrowsky GmbH

Oberfläche Möbel aus lasierten Fichtenholz

RKW Architektur

Sonnenschutz Textilrollo mit Handkurbel

Schrankwand

Wohnungstrennwände: Schallschutzanforderung R'w ≥ 53 dB Brandschutzanforderung F90

Schrankwand Balkone aus Betonfertigteilen auf Massivholzscheiben (accoya modifiziert) aufgelagert

Schubladen

Schreibtisch, ausklappbar, in Wand integriert RKW Architektur +

Wohnungstrenndecken: Schallschutzanforderung R'w ≥ 54 dB Trittschallschutzanforderung L'n,w ≤ 50 dB Brandschutzanforderung F90

Esstisch Schiebetür Klapptür

Oberfläche Möbel aus lasierten Fichtenholz

Nasszelle Höherweg 100 40233 Düsseldorf Telefon (0211) 821-4039 Telefax 821-774039 bhintzen@swd-ag.de

Brandschutzanforderung Tragende Bauteile: F90

Oberfläche Balkone aus Holz (accoya modfiziert)

Oberfläche Möbel aus lasierten Fichtenholz Glasgeländer

Trittschallschutzanforderung Balkone L'n,w ≤ 58 dB

Wandoberflächen weiß beschichtet

Esstisch

Co-Working Space, 1.OG, 2. OG

Sonnenschutz Textilrollo mit Handkurbel

Wohnungstrenndecken: Schallschutzanforderung R'w ≥ 54 dB Trittschallschutzanforderung L'n,w ≤ 50 dB Brandschutzanforderung F90

Abstellfl./ UV

Bodengleiche Dusche

Garderobenschrank

Trittschallschutzanforderung Balkone L'n,w ≤ 58 dB

Oberschrank Küchenzeile

Wohnen 1.-3.OG 8 Apartments

Installationsschacht

Wohnungstrennwände: Schallschutzanforderung R'w ≥ 53 dB Brandschutzanforderung F90

Küchenzeile

Installationsschacht

2 Wandabwicklung B - B

Grundriss Module

Fassade aus Holzschalung, accoya modifiziert

Wandabwicklung C - C

Außenwand Lärmpegelbereich III Maßgeblicher Außenlärmpegel La = 65 dB Schallschutzanforderung R'w ≥ 35 dB

Legende:

Fenster-/ Türelemente aus Holz, accoya modifiziert

Oberfläche mit H

Oberfläche weiß Glasgeländer

Oberfläche besc

Glas / Oberfläch Balkone aus Betonfertigteilen auf Massivholzscheiben (accoya modifiziert) aufgelagert

Holz - konstrukti

Boden mit versie Estrichplatten ve

Ansicht Module

Wandabwicklung Holzmodul - Apartment A1

1 2 3

RKW Architektur +

Floor plan Prefabricated housing unit Detailed facade

01/2018 - 07/2018

Scale 1:400 Scale 1:100 Scale 1:100

Timber Concrete

Images shown on this page are owned by RKW Architektur +

Handlauf Ø 40 mm seitlich an Geländer befestigt

Geländer Flachstahl 50mm, auf U-Profil geschraubt, feuerverzinkt

1.03

VARIOWOHNEN Funded Affordable and Mixed Housing

ACMS_

Stahlprofil U240 als Treppenwange

Project location Bochum, Germany

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend Overview R11, untereinander verschrauben The project was part of the programme

Architect ACMS_Architekten GmbH 19

Knowledge acquired I considerably extended my competences for “Variowohnen” (Vario-living) which is funded planning energy and resource-efficient buildings. by the Federal Ministry for the Environment, I gained much knowledge of prefabricated timber Laerheide Bochum Bauvorhaben: Nature Conservation and Nuclear Safety. Due to constructions and their benefits. Furthermore, 4-8 with engineers was an enriching the hybrid construction consisting of a partially Laerheidestr. collaborating 44799 Bochum precast concrete skeleton and prefabricated experience. timber facade elements, theBauherr: construction time AKAFOE Universitätsstraße 150 could be diminished by approximately ten months. The building complex revitalises an old 44801 Bochum mining area and provides a mix of apartment sizes and common rooms, despite a tight budget and minimised area required.

184_AKAFOE Laerheide_LP5

Project participation 04/2017 - 09/2017

HEA 140

Team Christian Schlüter, Angelika Austin Client Akademisches Förderungswerk Bochum

Kragträger HEA 140 Role Anschluss an Außenwand Certification I joined the project during the construction DGNB “Gold”, Passive house standard thermisch getrenntplanning phase. I was responsible for drawing Siehe Detail 184_W_64.25-4) plans and construction details, particularly

Publications “Detail Edition: Modulbau” (2019) “Deutsche Bauzeitschrift” (01/2017) Software Allplan

Ar M

the facade details, ranging from scale 1:50 to 1:5. Besides, I was in charge of planning and Stütze HEA 180 coordinating the design of the fire steel stairs in collaboration with the structural engineer. The drawings shown are samples of my contribution.

1 2

Variowohnen

Exterior view: Façades Site plan

Photo: Sigurd Steinprinz

Änderungen 0 Basisplan

31.08.2017 jad

Images shown on this page are owned by ACMS Architekten GmbH

1) Deckenanschluss

2) Deckenanschluss mit Fenstersturz

165 10

Lüftungsgerät

Lüftungsgitter des Leibungskanals Fort- und Außenluft, dezentrale Lüftung der Einzelapartments Aussparungsgröße in Fensterzarge: b / h = 8,0 / 34,0 cm

Lichte Raumhöhe 2.55

UK Lüftungsgerät = 1,16 ü. OKFF

Kunststoff-Fenster Uw ≤ 0,89 W/m2K Uf ≤ 1,0 W7m2K Ug ≤ 0,6 W/m2K SSK 2 oder 3 Einbruchschutz EG: RC2 Farbe nach Wahl des AG, z. B. anthrazit

Leibungskan Fort- und Au Lüftung der Lage in Hint

3. Obergeschoss

Geländerstab als Absturzsicherung Rundrohr Edelstahl OK = 0,90 ü. OKFF 335

Außenwand Brandschutz Wärmeschu

155

1) Antritt

PU-Formteil, WLG 025; Fensterabklebung außen, winddicht

+12.35 Fensterbank = 0,50 BRH

125

30 1

Horizontale Brandschürze Stahlblech, 2 mm Schraubenabstand ≤ 300 mm, U 240 pulverbeschichtet, Farbe nach 30 1 1 Wahl des AG, z. B. dunkelgrau +11.59 UK Element

+6.03 OK Gitterrost 5

+8.80

ACMS_Mineralwolle Schmelzpun

Stahlprofil U240 als Treppenwange

Gitterroststufen 1200x305 mm, TS: 50/3, MW: 30x30 mm, feuerverzinkt rutschhemmend R11, mit Antrittskante

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend R11, untereinander verschrauben

KVH 8/14

Kleintierschutz

Hohlräume v

184_AKAFOE Laerheide_LP5 Bauvorhaben:

Laerheide Bochum

Bauherr:

44799 Bochum AKAFOE

24 19

KVH 65/120

Planungsphase 5

Bauherr:

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend R11, untereinander verschrauben

VK GK Bekleidung ▼

VK Stütze ▼

ACMS_ Bauvorhaben:

Laerheide Bochum

Bauherr:

44799 Bochum AKAFOE

Laerheidestr. 4-8

Übersicht Treppendetails

4) Anschluss Kragträger an Außenwand

Stahlprofil U 240

2. Obergeschoss

Änderungen 0 Basisplan

Fluchtreppe, Details 3/3 Datum

Planungsphase

Plannummer

Werkplanung

184_W_64.30-05

1.03

Index

31.08.2017 0

Architekt:

Datum - Unterschrift

Maßstab

1:5

ACMS Architekten GmbH Friedrich-Ebert-Straße 55 42103 Wuppertal T 0202 445710 F 0202 4457158 info@acms-architekten.de www.acms-architekten.de Geschäftsführer: Michael Müller Prof. Christian Schlüter-Vorwerg Dipl.-Ing. Architekten BDA Olaf Scheinpflug Dipl.-Ing. Architekt AG Wuppertal HRB 12545

Geländer Flachstahl 50mm, auf U-Profil geschraubt, feuerverzinkt

Allplan 2015

1.015

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend R11, untereinander verschrauben Kragträger HEA 140 Anschluss an Außenwand thermisch getrennt

Gitterroststufen 1200x305 mm, TS: 50/3, MW: 30x30 mm, feuerverzinkt rutschhemmend R11, mit Antrittskante

Konsole zur thermischen Trennung z.B. Schöck Isokorb Modul KSTQ16 oder gleichwertig

105

Stahlprofil U240 als Treppenwange

185

5 0 3

1.03

459

Stütze HEA 180 Kleintierschutz

+3.15 OK FF

35 5

218

4 13

163

133

ACMS_

55 1

15 5

5 67

+3.015

+3.00 OK RD

184_AKAFOE Laerheide_LP5

HEA 140

Bauvorhaben:

Laerheide Bochum

Bauherr:

44799 Bochum AKAFOE

Laerheidestr. 4-8

142

+3.16

+3.08

Unterbau 30,0 cm Schotter 0/45

+3.13 OK Gitterrost

4 19

Oberbau Betonplatten Brechsand-Splitt-Gemisch 0/5 Schotter 0/45 Planum

Bodenaufbau Gehwege

5,0 cm 4,0 cm 21,0 cm •

±0.00 OK FF = 141,50 m üNN -0.02 OK Gelände = 141,48 m üNN

Stahlprofil U240 Fundament fehlt Angaben Staik

2545 30

Kleintierschutz

Universitätsstraße 150

44801 Bochum

+2.80 UK RD

2455 A2

5 03

1725

775 B2

383

6 Änderungen 0 Basisplan A Trägerstoß angepasst

1 2 3

Detail: prefabricated timber facade elements Interior view: Shared space Exterior view: Exit steel staircase

Scale 1:10 (1:5) -1.01

Photo: Sigurd Steinprinz Photo: Sigurd Steinprinz

4 5 6

Detail: Stair egress Isometry railing corner joint Detail: Connection staircase to exterior wall

04/2017 - 09/2017

Images shown on this page are owned by ACMS Architekten GmbH

31.08.2017 jad 20.06.2018 chs

Scale 1:20 (1:5) Scale 1:20 (1:5) Planbezeichnung

Fluchttreppe, Details 2/3 Datum

Planungsphase

Plannummer

Werkplanung

184_W_64.25-05

Bauherr:

Datum - Unterschrift

ACMS_Architekten GmbH

Det

Planbezeichnung

H/B = 594 / 841 (0.50m²)

-0.21

Kun Uw Uf ≤ Ug SSK Einb Farb z. B

Ansc

31.08.2017 jad

Datum - Unterschrift

305

PUFen wind

2 2

Architektur-Contor Müller Schlüter

Universitätsstraße 150

Stahlprofil U 240

1:5

Datum - Unterschrift

44801 Bochum HEA 140

Maßstab

184_AKAFOE Laerheide_LP5

Bauherr:

Index

31.08.2017 0

Datum - Unterschrift

335

Datum Architekt:

H/B = 594 / 841 (0.50m²)

Geländer Flachstahl 50mm, auf U-Profil geschraubt, feuerverzinkt

855

184_W_64.20-05

Handlauf Ø 40 mm seitlich an Geländer befestigt

171

Plannummer

5 Werkplanung 4

855

181 8

2 Planbezeichnung

1.015 35

133

3. Obergeschoss

HEA 140

3) Antritt Fundament

HEA 140

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend R11, untereinander verschrauben

Fen Alum gek Geh pulv Farb

Außenmaß Fensterzarge 2,15

1 35

Fensteröffnung i.L. 1,96

Fensteröffnung RBM 2,00

Lichte Raumhöhe 2,55

Geländer auf Stahlprofil U240 befestigt: Flachstahl 50/10 Obergurt: Flachstahl 50/10

10 20

Änderungen 0 Basisplan

Fluchttreppe, Details 1/3

Rohbauhöhe 2,70

12 15

Hor Stah Sch 31.08.2017 jad pulv Wah

Geschosshöhe 2,90

333

23 1

Abklebung innen, luftdicht

Geländer auf Stahlprofil U240 befestigt: Flachstahl 50/10 Obergurt: Flachstahl 50/10

Füllholz zum 3 2

+8.52 = 2.475 ü.OKFF +8.505 UK Sturz = 2.46 ü.OKFF

Auflagerwinkel Stahl gem. Statik

Handlauf Ø 40 mm seitlich an Geländer befestigt

KVH 100/100 OSB4 t = 18 mm

8 2 1

855

Stahl-Verbundträger (Werkplanung Fa. BuM beachten!)

125

Stütze HEA 180

Elastomerauflager

466

Übersicht Treppendetails

Gitterroststufen 1200x305 mm, TS: 50/3, MW: 30x30 mm, feuerverzinkt rutschhemmend R11, mit Antrittskante

1.03

1.015

1 35

7) Isometrische Darstellung Geländerecke 1

3 4

VK Stütze ▼

Rohbauhöhe 2,70

Abklebung innen, luftdicht

Kragträger HEA 140 Anschluss an Außenwand thermisch getrennt Siehe Detail 184_W_64.25-4)

+8.60 UK RD = 2.55 ü.OKFF

Bekleidung außen - Lasur: Vorvergrauung ohne Bläueschutz - Formschlüssige Holzschalung, Baustoffklasse B2, normal entflammbar, Lärche, vertikal verlegt. Profil mit Nut und Feder, konstante Brettdicke: mind. 18 mm, verbleibende Dicke bei Profilierung: mind. 10 mm - 8,0 cm Luftschicht / Unterkonstruktion: Holzlattung/ -konterlattung Holztafelelement Holzanteil 16% - 1,5 cm Zementäre Bauplatte, Baustoffklasse A1, sd < 0,6 m, Stöße winddicht verklebt - Holzständer gemäß Statik: KVH 65/65, OSB-Platte 1,8 cm, KVH 65/65 - 30,0 cm Wärmedämmung MF WLG 035 Baustoffklasse A1, Schmelzpunkt > 1000°C - 1,8 cm OSB-Platte, sd > 3,6 m Bekleidung innen - 1,25 cm Gipsplatte, 1-lagig 4

Unterlegung, Lagesicherung

Quetschdich

855

▲ Fensterzarge

Drucklagerung / Unterlegung, Stahlblech

+5.67

Stütze HEA 180

Außenwandaufbau Brandschutzanforderung: F30 Wärmeschutzanforderung: ≤ 0,12 W/m2K

Auflagerwinkel Stahl gem. Statik

44801 Bochum

855

Be- und Entlüftung Spalt max. 3,0 cm

+11.42 = 2.475 ü. OKFF

Stahl-Verbundträger (Werkplanung Fa. BuM beachten!)

Lichte Raumhöhe 2,55

855

Kleintierschu

Universitätsstraße 150

HEA 140

305

6) Regeldetail Geländeranschluss

+11.56 OK Element

Elementhöhe 2,87

Elastomerauflager

Geschosshöhe 2,90

KVH 100/100 OSB4 t = 18 mm

Kragträger HEA 140 Anschluss an Außenwand thermisch getrennt Siehe Detail 184_W_64.25-4)

+11.50 UK RD = 2.55 ü. OKFF

171

2 2

KVH 65/120

3 2

133

+5.85

5) Geländeranschluss im Stützenbereich

U 240

Spannbetonhohldiele 20

133

HEA 140

Spannbetonhohldielen

Elementschw als Brandrie

Laerheidestr. 4-8

auf U-Profil geschraubt, feuerverzinkt

2075

Quetschdichtung, winddicht

Füllholz zum Toleranzausgleich 27 +3.13 OK Gitterrost

Geländer

+8.95 OKFF 3.OG

181

KVH 8/14

3 33Flachstahl 50mm,

05 6 35

125

Abklebung innen, luftdicht

Stahlprofil U240 als Treppenwange +3.31

Gitterrost TS: 50/3, MW: 30x10 mm, feuerverzinkt, rutschhemmend R11, untereinander verschrauben

Elementschwelle / Brandriegel mit b ≥ 4 cm

+11.70 OK RD

466

Handlauf Ø 40 mm seitlich an Geländer befestigt

Mineralwolle Schmelzpunkt ≥ 1000°C Hohlräume vollständig ausstopfen

+11.85 OKFF 4.OG

+6.88

Kleintierschutz

5,0 cm 20,0 cm

1.03

• 3,5 cm

Geländer Flachstahl 50mm, auf U-Profil geschraubt, feuerverzinkt

171

30 18

Abklebung innen, luftdicht Verschraubung M12 [G16] in Modix-Muffe [G13]

125

2075

1.03

5,0 cm 20,0 cm

6,0 cm Handlauf Ø 40 mm seitlich an Geländer befestigt

Bodenaufbau OG 2 Linoleum 2,5 mm, vollflächig verklebt, vollflächige Spachtelung Zementestrich CT-F5-S60 Verkehrslast bis 3,00 kN/m2 Trennlage, PE-Folie Trittschalldämmung EPS DES s' 10 MN/m3 Ausgleichsschicht EPS 035 DEO Spannbetonhohldiele 5

0,5 cm

Fensterzarge Aluminiumblech, mehrfach gekantet, in den Ecken auf Gehrung, mit Antidröhnstreifen, pulverbeschichtet, Farbe n. Wahl d. AG

+3.98

• 3,5 cm

KVH 80/65 18

KVH 65/65

Bodenaufbau OG Linoleum 2,5 mm, vollflächig verklebt, vollflächige Spachtelung Zementestrich CT-F5-S60 Verkehrslast bis 3,00 kN/m2 Trennlage, PE-Folie Trittschalldämmung EPS DES s' 10 MN/m3 Ausgleichsschicht EPS 035 DEO Spannbetonhohldiele

Zusätzliche Abdichtung im Fensterbankbereich, Elastomer-Abdichtungsbahn, 2 seitlich 15 cm hochführen

+4.16

OSB4 t = 18 mm

Fensterbank Stahlwinkel Auflager Fensterbank

6,0 cm

0,50 BRH

+12.32

Bekleidung - Lasur: Vorv - Formschlü Baustoffklas Lärche, vert Profil mit Nu konstante B verbleibende Profilierung: - 8,0 cm Luf Holzlattung/ Holztafelele Holzanteil 16 - 1,5 cm Zem Baustoffklas winddicht ve - Holzstände KVH 65/65, - 30,0 cm W 6 Baustoffklas - 1,8 cm OS Bekleidung - 1,25 cm Gi

1.52

Abklebung innen, luftdicht

0,5 cm

Übersicht Treppendetails

2) Austritt Schreibtisch

103

1.52

Schreibtisch Fensterabklebung innen, luftdicht

Fensterzarg

WD Lüftung Ø 125 Achse 1,52 m ü. OKRD

Achse Durchdringung

Geschosshöhe 2.90

+13.01

Öffnung in Leibung der Fensterzarge b/h 8/36 cm

Rohbauhöhe 2.70

Außenmaß Fensterzarge 2.15

394 195

4. Obergeschoss

Det

Elementhöhe 3,825

Fensteröffnung i.L. 1.96

Detail 184_W-51.30

Achse Durchdringung

Lüftungsgerät

Lichte Raumhöhe 2.55

Rohbauhöhe 2.70

Fensteröffnung RBM 2.00

Anschlussdetail 184_W-50.00

43 H/B = 594 / 841 (0.50m²)

Index

20.06.2018 A

Architekt:

Datum - Unterschrift

Maßstab

1:5

â&#x20AC;&#x153;Sustainable technologies must be combined with a philosophy of sustainability, a thorough understanding of how important the Earth is to us, resulting finally in a new architecture and a new visual language.â&#x20AC;? 1

Anne Taylor (2009, p. 364)

Complete Portfolio: https://issuu.com/jan. dankmeyer

THANK YOU FOR YOUR TIME! jan.dankmeyer@gmx.de +46 79 339 56 81 I would like to hear from you.