Chen Sikai Portfolio_Testing_DONT LOOK by Chen Si Kai

DESIGN PORTFOLIO CHEN SIKAI

C O N T E N T

Studio Design

Project 1

Project 2

Project 3

Title: The Stone Designer: Chen Sikai

Title: SUTDx: Accumulation Designer: Chen Sikai

Title: The Void Forest Designer: Chen Sikai

Time: 2015 Content: - Introduction to the Project - Concept Processing - Technical Drawings

Time: 2016 Content: - Site Analysis - Concept and massing process - Building Block analysis - Plans and Sections

Time: 2016 Content: - Site Analysis - Concept and massing process - Facade Details - Plans and Sections

Computation Design

Structure Design

Project 4

Project 5

Project 6

Title: Tube House Designer: Chen Sikai/Cheryl Lim Jia Li/Low Wei An/Porndee Chua/Zhou Xinyi

Title: TAKING FLIGHT Designer: Chen Sikai/Low Wei An/Christyasto P.P/Lee Hyosoo

Title: layers Designer: Chen Sikai/Mok Junwei/Zhou Xinyi/Neo Xinhui

Time: 2015 Content: - Concept - Coding Explanation - Technical Drawings

Time: 2016 Content: - Concept - Coding Explanation - Technical Drawings - Fabrication

Time: 2015 Content: - Technical Drawings - Connection Details

Furniture Design

Project 7 Title: Inside Out Chair Designer: Chen Sikai/Low Wei An/Lee Hyosoo/Christyasto P.P Time: 2015 Content: - Concept - Coding Explanation - Simulation result Explanation - Technical Drawings

P R O J E C T

The Stone

Design by Chen Sikai

ABOUT This project asks for a design in an open and natural space in Tampines area, Singapore. Diversity in the boundary conditions of the plot like the MRT station and different types of roads and pathways, the buildings that are framing the space, accessibility, close amenities, potential users, character of the different traffic roads, etc. will be taken into account to produce a building thoroughly connected to its close environment. I developed a personal approach to deal with an urban yet natural context, and explored strategies to arrange the required exterior and interior spaces within a consistent and relevant design, carefully inserted in the site. Hence, I came out will idea of â&#x20AC;&#x153;Stoneâ&#x20AC;?: The building will placed one the center of the site and attract guest from surrounding to the point, which like the mile stone of the site

Site and Massing

SPACE USERS INTENSITY

VENTILATION SITUATION

SCALE 1:2000

VIEWING RANGE

ROADS

Main Enterance Main Enterance

Simple Box

To Theatre

Two sides are titled to create entrances

To Theatre

- Change height of entrances to create to the level difference between enterance -Open the wall to create the facade pattern

Apply the space underground to create the theatre space

Central Yard introduce the light into the interior space

Plans

CENTRAL YARD

CENTRAL YARD EXHIBITION HALL

EXHIBITION FLOOR

Third Floor

Second Floor

SCALE 1:200

READING SPACE CAFE

THEATER SOUND ROOM

Basement

Ground Floor

CENTRAL YARD

SCALE 1:200

SUNLIGHT EMSSION AND VENTILATION

P R O J E C T

SUTDx: Accumulation Design by Chen Sikai

ABOUT This project ask for the design of a satellite SUTD building in the intersection of Bras Basah, Prinsep, Orchard and Handy Road. SUTDx is the universityâ&#x20AC;&#x2122;s downtown anchor among the network of universities and institute of higher learning. Riding on the success of SUTD Event Space in the intersection of Orchard and Cairnhill Road, SUTDx mirrors the first projectâ&#x20AC;&#x2122;s programmatic functions; housing flexible space for public events, recruitment efforts, strategic involvement in SkillsFuture initiative, providing basic classrooms/learning spaces, lecture theatres, exhibition paces, cafe and administrative offices.

Site Analysis

1 Green Land is located beside the site

4 Buildings are commerical and entertainment function

2 Buildings are cultural and tourism related function

1 Building is related to religion 1 Building is mixed with educational function

6 Buildings are the academic and educational function

Traffic Indensity

Overall Guest Flow

Figure-Ground

Potential Access and View

Massing Process

Straight Viewing

Opened Viewing

Wide Viewing + Direction Guide

Opened Viewing + Direction

Site Plan

Scale 1:2000

Plans and Sections Student Lounge

LEVEL 4 A’

Office

Pantry Classroom Office

Classroom

LEVEL 3

Classroom

B’

ur e

tre

oo sr

C la

ro o

y ar ibr i-L Min

roo

Cla

LEVEL 2

C’

Cafe

Lecture Theatre 1

Office

Exhibition Hall

Office

Scale 1:600

sion

cus

Dis

Class

room

Classroom

Roo

sion

cus

Dis

Roo

GROUND FLOOR Scale 1:800

Building Block Analysis

The higher levels are private space for the users to study, interact and work. Nice views will be given and avoid the noise from the ground.

The middle blocks are semi-private for the public who are interested in the SUTD to learn more about this school, include the open classroom and lecture thearers. Give the good views for space users

Ground Floor is public floor, more flexible space and arrange, allow public enter or pass through blocks

P R O J E C T

The Void Forest Design by Chen Sikai

ABOUT Working on the scales of the city, the building and the individual unit the studio aims to understand the complex nature of urban contexts as places for habitation and the mutual potentials evolving between them. The studio project will develop innovative urban housing concepts for sustainable high-dense living and focus on themes like density, diversity and connectivity. The integration of building systems like load-bearing structure, services and building envelope will be treated as constitutive parts of design process. The site, Yishun, are located at the north area of Singapore, arrounded by the residential HDB and hence, need to link the design with the surrounding.

Site Analysis and Microclimate Studies Non-Residential Function

Greenery/Park

Residential Function

Road System Major Arterial Minior Arterial Primary Local Access

Building Layout

Figure Ground

Shadow Effect and Surrounding Environment

BUS

TAXI

NEIGHBORHOOD PLAZA MRT

2 3

DATE: 21 MARCH AND 21 SEPTEMBER 1. At 10 AM: Only the connection to MRT Station are shaded 2. At Noon: Whole site are exposed to sun 3. At 16 pm: Only the edge near to neighboorhood plaza are shaded

1. Main Vehicular Routes 2. Principal Pedestrian routes 3. Location of nearby Public open space/Greenary and views 4. Location of local communal and commerical space

BUS SHOPPING MALL

BUS INT

NEE SOON CENTRAL COMMUNITY PARK

UNDERDEVELOPED LAND

YISHUN POND

CYCLING LINK UNDERDEVELOPED LAND

YISHUN PARK

YISHUN TOWN GARDEN

Massing Strategy

Normal HDB Void Deck

Public Void Deck With Different Ceiling Height

Semi-Public Void Deck for residents

Introduce Different types of Void Deck

Different Height of towers to respond the site

SHADOW EXPECTED

BUS STOP

TAXI

Neighborhood Commercial area

YISHUN MRT STATION

Expected shadow and path

Towers Arranged by grid

Rotated by sunpath and views

Landscape and Canopy Design by same grid system

Massing and Void Study Type I: Public Void Deck - Walking Path

Structure Idea

- Directing - Public Activities - Commercial

Facade

Type II: Residential Communal Void Deck - Buffer Zone - Residential Communal Space -Extension Space

Commercial Residential

Program Distrubution

Type III: Private Void Deck - Large Size Balcony - Vertical Personal Garden - Visual Connection

General Circulation

Type IV: Cluster Void Deck - Cluster Unitsâ&#x20AC;&#x2122; Communal Space - Sharing and Extension space for units

Facade Details

Heat Proof Layer Roof Water Proof Layer

Structural I-Beam

30mm Clear Vision Glass Back Mullion

200mm Floor Finishing Layer

400 mm Reinforced Concrete floor slab Slicon Sealing Layer 1200mm X 2000mm X12.5mm Rigitone acoustic ceiling boards

Insulation 20mm Structural Connection Steel STUD

Ground

Unit Type I Studio Apartment with SOHO space

Toilet

Bedroom

Toilet

Bedroom

Living Room and Kitchen

Bedroom Living Room and Kitchen

SOHO Space

Toilet

SOHO Space

Bedroom

Living Room and Kitchen

SOHO Space

Meeting Space

Level 1

Level 2

Unit Type II Studio Apartment

Living Room and Kitchen

Toilet

Bedroom

Toilet Living Room and Kitchen

Bedroom

Meeting Space

Bedroom Toilet

Level 1

Living Room and Kitchen

Bedroom Toilet

Level 2

Living Room and Kitchen

Bedroom Toilet

Level 3

Living Room and Kitchen

Unit Type II Studio Apartment for 2 members

Toilet

Toilet Bedroom

Bedroom

Living Room and Kitchen

Living Room and Kitchen Bedroom

Toilet

Bedroom Toilet

Plan and Section

Level 7 Site Plan

Site Section AA

Scale 1:200

Scale 1:1000

0m Scale 1:400

P R O J E C T

Tube House

Design by Chen Sikai/Cheryl Lim Jia Li/Low Wei An/Porndee Chua/Zhou Xinyi

ABOUT The Project site is located in Ho Chi Minh City, Vietnam.The house in Vietnam has the unique characters: long but narrow. Hence,it provides the chance for architects to design the special house like a tube. As the requirement, we need to design the ceiling, facde and the massing of the tube house with dimension of 4 meters width, 12 meters depth and 4 floors height. The house are required for natural ventilation and lights but prevent from the raining and direct sunlight during lunch hours. Hence, we come out with the idea of â&#x20AC;&#x153;across chessboardâ&#x20AC;? for the facade and ceiling. It will allow the indirect sunlight to enter the house with the natural ventilation come into house. In the meanwhile, it will create the nice outlooking for the entire house as well. The project combined structure, computation and design studio work.

Concept Why Air Ventilation? We feel that in tropical Vietnam, heat is an endemic issue exacerbated by the crowded urban conditions and unaffordability of air conditioning to a major segment of the population. As such, we want to focus on naturally ventilating the building as a primary issue. Our Plot, P3, is ideally located for receiving wind (arrow) during the summer months.

With neighbouring buildings at close proxmity, we also wanted to focus on privacy as a secondary issue.

Hot air rises Cross ventilation Cool air rushes in Uniform cross ventilation

Sliding to drive ventilation

a. A smaller volume

b. Sliding to introduce voids

c. To achieve effective ventilation break the block before sliding

Concept Why Air Ventilation?

Due to long and narrow nature of the building, the size of void have to be carefully designed to maximize the functionality of the space

Facing out

Wind enter from the side to aid cross ventilation. Steel and glass panels have alternate arrangement. Opaque steel panels aid in protecting privacy. Use of glass panels allow light to enter.

Facing out

Technical Drawing

The frame is patterned by N-shaped steel beams. These provides extra support for the load and also connects the inner and outer layers of panels together.

L hinge to attach the facade frame to side wall so as to provide structure support for the building

The reinforced concrete floor is not only load-bearing, but also integrated into the building structure to provide the support for the facade frame to hamper the frame structure from bending.

The tiling panels are divided into two layers and slightly offseted from each other: 1) outer layer: panels are transluscent enough to transmit light but not betray inside movement. 2) inner layer: panels are transparent to

Facade Pattern Coding (Grasshopper) Explanation nu: the number of vertical lines nv: the number of horizontal lines up,vp: percentage List<Line> l1 = new List<Line>(); List<Line> l2 = new List<Line>(); List<Point3d> pts = new List<Point3d>();//List for intersection points List<Surface> sf1 = new List<Surface>(); List<Surface> sf2 = new List<Surface>(); s.SetDomain(0, new Interval(0.0, 1.0)); s.SetDomain(1, new Interval(0.0, 1.0));¬¬ double du = 1.0 / (double) (nu - 1); double dv = 1.0 / (double) (nv - 1); double delta = (1.0 - vp) * dv / 2, a, b;//delta: the length of Point3d p1, p2; for (int j = 0; j < nv; j++) { if (j == 0 || j == nv - 1) { p1 = s.PointAt(0, j * dv); p2 = s.PointAt(1, j * dv);//Make two edges always horizontal, which will not change the angle whenever “vp” changed. } else { p1 = s.PointAt(0, j * dv + ((j % 2 == 0) ? delta : -delta)); p2 = s.PointAt(1, j * dv + ((j % 2 == 1) ? delta : -delta));//Find the points on two vertical boundries according to the “delta” } l1.Add(new Line(p1, p2));//Draw the line connecting p1 and p2 and get the horizontal lines. } delta = (1.0 - up) * du / 2; for (int i = 0; i < nu; i++) { if (i == 0 || i == nu - 1) { p1 = s.PointAt(i * du, 0); p2 = s.PointAt(i * du, 1); } else { p1 = s.PointAt(i * du + ((i % 2 == 0) ? delta : -delta), 0); p2 = s.PointAt(i * du + ((i % 2 == 1) ? delta : -delta), 1); } l2.Add(new Line(p1, p2)); }

x: the list of points on one layer y: the list of points on another layer List<Line> lines = new List<Line>(); for (int j = 0, k = 0; j < nv; j++) { for (int i = 0; i < nu; i++, k++) { if (i != nu - 1) { lines.Add(new Line(x[k], x[k + 1])); lines.Add(new Line(y[k], y[k + 1])); if ((i + j) % 2 == 0) lines.Add(new Line(x[k], y[k + 1])); else lines.Add(new Line(y[k], x[k + 1])); } if (j != nv - 1) { lines.Add(new Line(x[k], x[k + nu])); lines.Add(new Line(y[k], y[k + nu])); if ((i + j) % 2 == 0) lines.Add(new Line(x[k], y[k + nu])); else lines.Add(new Line(y[k], x[k + nu])); }

for (int j = 0; j < nv; j++) { for (int i = 0; i < nu; i++) { if (Rhino.Geometry.Intersect.Intersection.LineLine(l1[j], l2[i], out a, out b)) pts.Add(l1[j].PointAt(a)); } } //Get the points of intersection between vertical lines and horizontal lines.

lines.Add(new Line(x[k], y[k])); for (int j = 0, k = 0; j < nv - 1; j++, k++) { for (int i = 0; i < nu - 1; i++, k++) { if (((i + j) % 2 == 0) == sel)//Use Boolean which can change the place of surfaces. sf1.Add(Rhino.Geometry.NurbsSurface.CreateFromCorners(pts[k], pts[k + 1], pts[k + nu], pts[k + nu + 1])); else sf2.Add(Rhino.Geometry.NurbsSurface.CreateFromCorners(pts[k], pts[k + 1], pts[k + nu], pts[k + nu + 1])); } } //Use the points of intersection to make the surfaces needed. A = sf1; B = pts; C = sf2;

} } A = lines;

Front View

Back View

Top View

Section

P R O J E C T

TAKING FLIGHT(Jointed Shelter Frame)

Design by Chen Sikai/Low Wei An/Christyasto P.P/Lee Hyosoo

ABOUT The Project site is the school wide project. We are required to select one place in the university (Singapore University of Technology and Design,SUTD) campus area, then design and fabricate the structure for exhibition purpose. We come out with the design of the space frame structure by using the Grasshopper computation. And then we chose the 1 meter wooden rods to construct the frame out. As the team, we design the seat jointed pavillion frame and become one of the interesting exhibition frame in the campus.

Concept Design Concept Following the idea of letting 'imaginations take flight', we wanted to create a shelter that resemble the motion of taking flight. In addition to this, because our site is located at the midst of the planter areas, we took inspiration from the nature. Inspired by dandelion petals flying off to the air, the form of our structure intends to express the motion of taking off and reaching towards the sky. The shelter provides the users a space where users can reflect and ponder about their ideas while viewing the airplanes taking off Image source: bridgedesign.com

Structure Concept DIAGRAMMATIC FORM

SPACEFRAME

The original structural concept was to design a lightweight fabric structure, however, the single layered structure is prone to slack due to its weak structural properties. Furthermore, since our structure is placed outdoor, the structure needs to be strong enough to withstand the wind and rain loads. For a more stable structure, we designed a mesh frame that will provide more stability for the structure.

Grasshopper Coding

Form-finding The Grasshopper code generates a space frame that is made up of pyramid-shaped elements. From the spaceframe generated, we adjust the nodes to create the form that we intended.

Technical Drawings

80mm

400mm 600mm FRONT ELEVATION

1200mm

1450mm

1000mm

950mm

800mm

100mm

Dimension

SCALE 1:10

SIDE ELEVATION

elevation

SCALE 1:10

Joint details

NODE JOINTS

20m

3D printed joints are used to connect the wooden rods at complicated nodes with lots of connections. Therefore, we have designed several different joints. The node joints connect ranging from minimum of 3 wooden dowels to maximum of 8 wooden

3D PRINTED JOINTS

LINEAR JOINTS m

100m

40mm 20mm 40mm

THREADED ROD JOINTS

Threaded rods are used to connect the wooden dowels. The rods are embedded 40mm into the wooden dowels to ensure a strong joint. The threaded rod joints reduce the bending of long linear elements by stiffening the midpoint.

Joint Type Design 3 JOINTS

5 JOINTS

4 JOINTS

6 JOINTS

7 JOINTS

8 JOINTS

SCALE 1:2

Fabrication

UNIQUE ID CODE To aid the fabrication and assembly process, a Grasshopper code is made to identify each wooden dowel at the respective location. When the number slider is moved, the code will highlight the wooden dowel location and show its length.

Fabrication Process

MARKING marking the dimensions on the headless screw and wooden rods

CUTTING cutting the headless screw according to the specified length with top handle jig saw

CUTTING cutting the wooden rods according to the specified length with wood cutting jig saw

SANDING sanding the edges of the cut wooden rod

5.5mm and 6mm DRILL BIT 5.5mm drill bit to create a hole suitable for 6mm headless screw

OUTLINING setting a guidline to drill the hold at the center using the mini drill machine

DRILLING drilling 5.5mm sized hole according to the specified depth

EMBEDDING embedding the cut headless screw to the cut wooden rod

JOINING joining the

DRILLING drilling 6mm sized hole according to the specified depth

3D PRINTING printing of 3D joints

FILING filing the 3D printed joints to remove unneccessary filaments and supports

APPLYING applying the wall putty on the void of the 3D printed joints

SANDING sanding the 3D printed joints for a smoother surface

SPRAYING spraying white paint on the 3D printed joints for a polished look

PAINTING painting the narrow corners of spray painted joints

JOIN joining the wooden rod by the 3D printed joints.

FIXING remove the mistaken structure joints

ASSEMBLING Assemble different parts of the structure as one

FIXING remove the mistaken structure joints

ASSEMBLING Assemble different parts of the structure as one

PLACING placing the structure frame on the seat

P R O J E C T

layers, a sanctuary in Pulau Hantu

Design by Chen Sikai/Mok Junwei/Zhou Xinyi/Neo Xinhui

ABOUT In this project, we were tasked to design and develop construction specifications for a shelter on Pulau Hantu. The shelter must have the maximum dimensions of 3 m by 6 m by 9 m for overnight or short term stays for researchers, who carry out environmental observations on Pulau Hantu, and possibly find a daytime retreat for discussion and writing. My group explored the idea of utilising timber as the main material of the structure. We were also played with the idea of having many horizontal and vertical elements that which density affects the amount of light and wind from entering the pavilion.

Technical Drawings Floorplan 1:20

Section A 1:20

Section B 1:20

Section C 1:20

Connection Detail A

Connection Detail B

Connection Detail C

Connection Detail D

P R O J E C T

Inside Out Chair

Design by Chen Sikai/Low Wei An/Lee Hyosoo/Christyasto P.P

ABOUT To create a complex geometrical form through combining simple angular elements. The main objective that we want to achieve is to design a chair that can transform its form depending on whether the chair is in use. When the chair is in use, it can be raised up into a 3-dimensional chair form, otherwise it can be collapsed and flatten into a 2-dimensional rectangular form which can be stored easily without taking much space.

Concept The chair is design to be used in a modern home setting. As homes in cities are getting smaller and smaller, there a need to design a furniture that can save space when it is not in use. Observing that furniture takes up most of the space in homes, we decided to design a chair that can be flatten when not in use and can be stored easily without taking too much space. Hence our design objective: a transformable chair that save space Through starting with a piece of rectangular wood, we explored different geometrical form by slicing the wood to identical rectangular strips. From the rectangular strips, we tried to fold each one of them at certain angles, then applied geometrical function to achieve different forms. We started from basic functions such as sine and cosine and went on to experiment more complicated functions.

Side View

Axonometric View

Front View

While exploring different geometrical possibilities with ‘V’ shaped structure, we intially experimented with the simplest function and form to observe whether the ‘V’ structures are stable enough to create a chair. To experiment this, we tried to make a miniscule chair using wood sticks that resemble the wooden strips. During the experiment, we have discovered that we had to add hook system for the actual product to prevent sliding when seated.

Function : ASinBCosC

Function : ASinC + BSinC

Function : SinA + Phase

Function : Sin

Function : ASinBCosC

Final Iteration

Grasshopper karamba force loading simulating Materials for testing: Wood, Steel and Aluminium Loads to apply: 1kN/m 1.5kN/m 16kN/m Due to the self-weight of chair (gravity), when the loads are not applied, chair is undergoing certain stresses but these stresses are negligible (0.4%). The stresses surface at the back rest region and seat because of the beams cantilievering. The highest stresse is taken by the horizontal chair legs due to the supporting functions by the legs. For the safety purpose, safety factor (1.5 and 3) is applied to test the structure strength of chair and through testing, the maximum load for the chair is 16kN/m, which means the chair will be able to take three times loads than the expected loads. When the materials changed, the safety factor will change accordingly. (Steel: Maximum Load 29kN/m; Aluminium: Maximum Load:15kN/m) Steel

Aluminum

Expected Load

1.5 Factor Load

Maximum Load

Expected Load

Wood

1.5 Factor Load

Maximum Load

Expected Load

1.5 Factor Load

Maximum Load

Technical Drawing

Hinge Detail 1

Hinge Detail 2

Hinge Detail 3

Axis Detail

Hook Stopper Detail

Gravity / Without Loading

With Loading Side View

Top View

Facade Pattern Coding (Grasshopper) Explanation

The code first generates the long and short sections of each rib of the chair based on specific periodic function

The next part takes the long sections and the corresponding short sections and joins them in such a way that the end points can be moved together. This creates an adjustable legs that can be controlled by the â&#x20AC;&#x153;setbackâ&#x20AC;? input argument in grasshopper

A B O U T

Chen Si Kai

Undergraduate Architecture student

Born in China in 1991 Bachelor of Science (Architecture and Sustainable Design) May 2014 - Aug 2017 Singapore University of Technology and Design

Diploma in Aerospace Engineering with Merit May 2011 - May 2014 Republic Polytechnic,Singapore

Airport Master Planner and Designer (Intern) May 2016 - Aug 2016 Surbana Jurong Private Limited, Aviation Department Involved Projects: - Male Ibrahim Nasir International Airport (Maldives) Seaplane terminal re-design project - Changi Airport Terminal 5 Master Planning - Jakarta Soekarno-Hatta International Airport (Indonesia) Cargo terminal Master Planning - Wattay International Airport (Laos) Airport Re-design Project

Chen Sikai

Email:sikai_chen@mymail.sutd.edu.sg Contact: (+65)8322 4419 Address: Blk 55 #04-29 Changi South Ave 1 Singapore 485997