Architecture Work Sample
Congqi Wang
https://issuu.com/congqiwang06181996/docs/2020_portfolio_to_issue
Congqi Wang Email: congqiwang@alumni.upenn.edu Tel: 267-881-7659
Education 08.2019-12.2020
09.2014-06.2019
University of Pennsylvania Philadelphia, US Master of Science in Design-Environmental Building Design Central South University Changsha, China Bachelor of Architecture *GPA:3.82/4.0
09.2020-Present
Carl Massara Architect. LLC -Assistant Architecture Designer -Philadelphia, US
Professional Experience
06.2020-08.2020
Plan drawing for urban residential apartment project;
Plan and Facade drawing for housing projects in AutoCAD;
Physical Model Fabrication for residential projects;
3D Digital Model built in Rhino and interior render for residential projects.
Robert Cohen Architect. LLC- Architectural Internship
-Westport, US
Energy Performance Simulation for office and residential projects;
Daylight simulation and data visualization for the proposed concept design;
Assist with the development of building simulation computer models of a building product that saves energy at windows. And assist in developing models that could reduce solar radiation at a window using the PTDH concept;
Assistance in cost analysis for the product based on energy savings and calculation of ROI;
Develop the final presentation of the simulation model and a shadow simulation video.
ͳͳǤʹͲͳͺǦͲʹǤʹͲͳͻ Ǥǡ Internship- Shanghai, China
Plan drawing of high-rise residential buildings;
Render of residential projects.
ͲǤʹͲͳǦͲͺǤʹͲͳ
Internship- Changsha, China
Surveying and Mapping Practice of Ancient Buildings in Historic Village
Design Competition ͲǤʹͲͳ
Finalist -Project: Rural Living Room
ͳʹǤʹͲͳ Ƭ ȋ Ƭ Ȍ
-Project: Rural Architecture in UA City
Proficiency
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LinkedIn: https://www.linkedin.com/in/congqi-wang-1424011a0/
Email: congqiwang@alumni.upenn.edu
Cloud Cover
Temperature
Solar Radiation
Humidity
[Flowable surface] Climate-adaptive Design for the Data Center of the Future Academic Project: Future Data Center Design Detroit City Climate Research: Group work with Xuezhu Sun, Xuehan Zhang Data Center Design:Individual Work
Studio Coordinator: Dorit Aviv Instructors: Zherui Wang, Kit Elsworth, Kian Wee Chen Spring 2020 Design Studio Model: Rhino/ Grasshopper Cliamte Data Visualization: GIS/ Grasshopper/CFD Render: Vray for Rhino
Email: congqiwang@alumni.upenn.edu
Site Analysis
Email: congqiwang@alumni.upenn.edu
CFD is applied to a wide range of research and engineering problems in many fields of study and industries, including aerodynamics and aerospace analysis, weather simulation, natural science and environmental engineering, indu engine and combustion analysis. In this research, we use CFD to simulate the wind condition in downtown Detroit. The direction of the arrows represent the wind direction in downtown Detroit. The length of the arrows represent the the wind pass through the gap between buildings. So we can use the shape or the envelop of the building to channel wind and use the wind pressure for cooling strategies. In the extremely cold Detroit winter, the wind comes from sout the climate of our site. Next we will think about how to make full use of the wind for passive cooling of the data center building.
In summer the wind mainly blows from the north-east and north. The average wind speed is 9m/s.
In spring the wind becomes a lot more humid. The wind mainly blows from west and northwest. The average wind speed is 7m/s.
ustrial system design and analysis, biological engineering, fluid flows and heat transfer, and e wind speed. From the above 3 season result, it can be seen the wind speed will change when thwest. From the analysis of the wind simulation result, we got a thorough understanding of
Email: congqiwang@alumni.upenn.edu
Interior Render of Data Center Server Space
Section and Programs:
Technology of Underground Heat Transformation:
Email: congqiwang@alumni.upenn.edu
Double-stack System for Surviving in a future of We Group work with Junjie Lu, Vidya Unnikrishnan, Navaz Bilimoria Fall 2020 Penndesign Arch754 - Performance Design Workshop Instructor: Jihun Kim Air Flow and Temperature or Radiant Temperature Simulation in Rhino CFD
Energy Flow Diagram with Chimney Effect in Summer
Energy Flow Diagram with Chimney Effect in Winter
Definition of Stack Effect Stack ventilation (also known as stack effect or chimney effect) creates airflow using the natural force that emerges from changes in air pressure, temperature, and density levels between corresponding internal and external environments. Chimney Effect is a useful design strategy in buildings that have greater depth, where cross ventilation may not be sufficient to penetrate to spaces in the center of the building. Stack ventilation is also feasibly for low-rise buildings that have a vertical volume where pressure differences can occur. Natural stack ventilation supplies and removes air from indoor spaces without the assistance of mechanical systems thus saving on a lot of cost induced by HVAC.
Combined Strategy with Underground Circulation System and Trombe Chimney
eather Extremity Summer
Fall
Winter
Energy Flow Diagram of Combined Strategy with Trombe Chimney and Underground System Velocity
Temperature
Velocity
Summer Simulation Result
Temperature
Winter Simulation Result
Future System Iteration1: Stack Ventilation+Geothermal system for Multi-Level Structure
Future Sysyem Iteration2: Double Stack Ventilation System
Winter Hypothesis
Summer Hypothesis
Email: congqiwang@alumni.upenn.edu
SIMULATION RESULT Extreme Hot
Stack Ventilation& Weather Extremity Extreme Cold
Temperature
Temperature
Velocity
Velocity
Radiant Temperature
Radiant Temperature
Conclusion The combination of Geothermal and stack effect works for indoor temperature control. The ventilation overall is shown to be high, with barely any air re-circulating. This cond however, we may need to improve air exchange rate to 100% to be really effective in th For winter, while ventilation seems to be efficient, we need additional heating sources f Future studies: we could like to explore how we can better control velocity and tempera hurricanes, extreme winters, and of course, rising temperatures due to global warming.
Iteration1: Stack Ventilation+Geothermal system for Multi-Level Structure
Iteration2: Double Stack Ventilation System
Temperature
Summer Velocity
Velocity
Winter Velocity
Radiant Temperature
dition would help in curbing the virus spread, his aspect. for winter months. ature for extreme weather conditions such as g.
Winter Velocity with Fan
Email: congqiwang@alumni.upenn.edu
[Far Beyond The Bridge] Rural Activity Center Design in South Hunan
Phase 1:
Phase 2:
Phase 3:
Academic Project: Rural Activity Center Designed for Left-behind Groups Individual Work Location: Yongzhou, Hunan, China Tutor: Ming Luo, Weidong Li Date: 07, Apr.2017-09, Aug.2017
Email: congqiwang@alumni.upenn.edu
Basic Unit For Usual State
Basic Unit For Festival Celebration
Composite Unit For Left-behind Children
Composite Unit For The Bazaar
Composite Unit For Left-behind Elderly
Composite Unit For Traditional Opera Performance
Basic Unit For Busy Farming Season
Composite Unit For Parent-child Interaction
Composite Unit For Grain Storage
Wooden frame mortise an Composite Unit For Tourists
Composite Unit For The Clan Rally
Composite Unit For Harvest Festival
Plan
nd tenon joint
Email: congqiwang@alumni.upenn.edu
Phase 1 of Smart Facade
[Smart Facade in the future cities] Academic Project Group Work with Junjie Lu, Vidya
Instructor: Billie Faircloth Studio Fall 2020
The current trends with regarding facades are a phenomenon which deserves this separate chapter. For this reason, today we will discuss different dynamic facades as follows.We could say that in the last few years, an additional function has been added to the well-known aesthetic, waterproof and insulating (thermal and acoustic) facades’ functions, that is the minimization of energy consumption. This is not exactly a new function, but rather an extension of the previous. Either through passive shading and ventilation, or through complex dynamic systems, the need to control a building’s interior environment in order to reduce our reliance on air conditioning, heating systems or artificial lightning, has led to the development of the buildings’ exteriors, made possible by technology.
Phase 2 of
Smart Facade
Phase 3 of Smart Facade
Pre and Post Simulation of Solar Radiation
Radiation Analysis Philadelphia Jun.21st
Radiation Analysis Philadelphia Jun.21st
Radiation Analysis Philadelphia Jan.1st 6:00-Dec.31st 18:00
Radiation Analysis Philadelphia Jan.1st 6:00-Dec.31st 18:00
Pre and Post Simulation of Visual Comfort
Email: congqiwang@alumni.upenn.edu
[Memory Restore]
Design of Aizhai Tourist Service Center
Individual Work Location: Jishou, Hunan, China Tutor: Mingjing Xie Date: 03, Mar.2019-06, Jun.2019
Email: congqiwang@alumni.upenn.edu
[INCOMPLETE WALLS] A House Designing for an Artist with a Cat and a Dog Academic work: Residential House Design Individual Work
Tutor: Ming Luo, Weidong Li Date: 03, Oct.2018-06, Dec.2018
Email: congqiwang@alumni.upenn.edu
Interior Render
Section
Email: congqiwang@alumni.upenn.edu
[ S PAC E D I V I D E D B Y A R C H STRUCTURE] Coffee Bar in Greater Philadelphia Competition: Coffeen Bar Design for Social Place Individual Work Location: Philadelphia, Pennsylvania, United States Tutor: Mingjing Xie, Ying Song Date: 07, May.2018-09, Aug.2018
Email: congqiwang@alumni.upenn.edu
[STATIC TORSION] Campus Shared Performance Theatre Design
Academic work: Campus Theatre Design Individual Work Tutor: Yu Wang, Weidong Li Date: 03, Mar.2018-06, Jun.2018
Email: congqiwang@alumni.upenn.edu
[Complementary work] Suspended Cable-arch Structure Team Work:Structural Selection Design 2016.06—2016.07/with He Jianing Leading Roll in Structure Design, Model Making
Suspended cable-arch structure is a load-bearing structure formed by flexible tension cable and its edge members. Rope material can be made of wire bundles, wire ropes, chains and other wire with good tensile properties. The arch at the centre lifts a net of cables extending outward, which consists of transverse load-bearing cables and longitudinal stabilisers. And the central arch is connected to the ground, so the load on the roof is partly carried by the central arch, and the other part is transmitted to the eaves on both sides by the cable network. The load is carried by the columns on both sides and dispersed to the ground. The advantage of suspended cable-arch structure is that it makes good use of the properties of metal materials. As the arch material used as the frame is metal, it can well withstand the transverse tensile force, so as to avoid the risk of being easily folded by shear force.
Email: congqiwang@alumni.upenn.edu
[Other work]01 Team Work:Youth Single Apartment Design with He Jianing Date: 14.Sep, 2017-10.Dec, 2017 Tutor: Yu Wang, Mingqiao Zhao
Email: congqiwang@alumni.upenn.edu
[Other work]02 THE RITTENHOUSE CONDOMINIUM Professional Project at Carl Massara Architect. LLC OCT2020 210 WEST RITTENHOUSE SQURE, UNIT2005-2006 PHILADELPHIA, PA 19103 Group Work with Jingyi Sun for contribution in the fabrication of physical model
Email: congqiwang@alumni.upenn.edu
[Other Work]03 Revit Skill Sample-Villa Savoye B
C
D
E
Top 9
Roof level 6
Floor Level 3
Ground level 0
Underground
Section
-3
Top 9
Roof level 6
Floor Level 3
193 / 1000
A
Ground level 0
Underground -3
East Elevation
UP
Top 9
Roof level 6
Floor Level 3
Ground level 0
Underground -3
1
South Elevation
2
3
1st Floor Plan
4
-
-
E
D
D 193 / 1000
-
E
C
C DN
5
B
B
A
A
1
2
3
2nd Floor Plan
4
5
Email: congqiwang@alumni.upenn.edu