Tamkang Univesity Architecture Selected Projects from EA1 - EA4
PORTFOLIO OF JCC ARCHITECTURE + DESIGN
2015 -2019
A Portfolio for EA5 Studio Selection
2015-2019 PORTFOLIO OF JCC / ABOUT ME
CHUN-CHUAN, LO / JCC Nationality: Taiwan, Tapei Date of Birth: 1997/02/16 Phone: +886 975 219 814 E-mail: jameslo0216@gmail.com Instagram: j_chunchuan Issuu: https://issuu.com/9988335/docs
2015-2019 PORTFOLIO OF JCC / CONTENTS
CONTENT
01
EA1_2
ACTIVE STSTEM
02
EA1_5
AUTO META
11~16
03
EA3_2
21 CENTURY SOCIAL HOUSING
17~32
04
EA4_1
INTERACTIVE PNEUMATIC INSTALLATION
33~42
05
EA4_2
VENEER FREE-FORM SHELL WEAVING FABRICATION
43~58
06
EA1_SUMMER
07
EA3&4_SUMMER
BUBBLE FARM DIGITAL AIEOU ROBOT WORKSHOP
5~10
59~60 61~62
2015-2019 PORTFOLIO OF JCC / EA1_2 ACTIVE SYSTEM
+ WOOD + JOINT + DOVETAIL + COMBINATION + TRANSFORM
2015-2019 PORTFOLIO OF JCC / EA1_2 ACTIVE SYSTEM
TRAINING PURPOSE Wood is a very important and very common material in architecture. Dovetail is a classic construction of traditional Chinese architecture. So the topic hopes that we can create a transformable system through the connection of designing unit.
PHASE_1
[ DOVETAIL ]
For me, the biggest purpose of dovetail is how to connect each other. Therefore, I did not just only focus on how to connect materials in the design, but more is on the connection between the units, this is the key point for me. On the unit, I designed the details that allow them to connect wirelessly to each other.
[ UNIT ]
[ DOVETAIL DETAIL EXPLOSIVE DRAWING ] [ JOINT ] 7
PHASE_2 The units create some space between each others after the connection, so that the combination can have the opportunity to make the form change.
[ EXPLODSIVE DRAWING ] 8
2015-2019 PORTFOLIO OF JCC / EA1_2 ACTIVE SYSTEM
CONCLUTION The shape will be manifested in two different states due to the different directions of the force applied. The gap between the units allows the whole to be deformed from 2D to 3D. In the process from concept to final model, I found that the spacing and thickness of the unit directly affect the elasticity and stability of the final deformation. But in this design, I tried to use the unit combination to present the material properties he can show. It can be regarded as a new attempt.
[ SOFT / HARD ]
9
[ 3D FORM ]
[ FORM_1 ]
[ FORM_2 ] 10
2015-2019 PORTFOLIO OF JCC / EA1_5 AUTO META
+ FLY + LIGHT + UNIT + COMBINATION + TRANSFORM
2015-2019 PORTFOLIO OF JCC / EA1_5 AUTO META
TRAINING PURPOSE There are many things in the nature that are worth learning from. The topic hopes that we can select an animal and refer to any of their dynamic behaviors as a reference for the development direction of the design.
PHASE_1 Inspired by animals’ body structure. I chose a movable part to evolve our design. Fly’s compound eye will change it’s structure between day and night. So I select it to be my object of study.
[ FLY ]
13
[ UNIT TYPE_1 ]
[ UNIT TYPE_2 ]
PHASE_2 To imitate compound eye’s change of state, I use unit and unit to simulate the eye element. In addition to the linking structure, there are diffierent transparency of plastic board between units. They transformed when the combination change form, at the same time it effect the influx that pass through units.
[ LIGHT CHANGE ]
MOLD MAKING Because the units are tubular, it is a bit difficult to manufacture, so the aids are designed to help the manufacturing. 14
2015-2019 PORTFOLIO OF JCC / EA1_5 AUTO META
CONCLUTION The structure between the units will change due to the overall shape change, and then illuminate the way the light passes through. In the deformation of the unit, it is limited by the length of the water pipe and the position of the steel wire on the unit.
[ DETAIL ]
[ CONNECTION ]
15
[ LIGHT ]
[ MODEL ]
16
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
+ ADAPTABLE + SOCIAL HOUSING + MODULAR
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
RETHINKING OF 21ST CENTURY SOCIAL HOUSING Since the turning of the century, the advancement of information technology, and the awareness of environmental sustainability have to lead to the change of consumer behavior and shifted the global economy from traditional linear consumption toward circular consumption to avoid the traditional material and energy, intensive business model. Such a shift creates a major impact on commodity production and consumer behavior allows the world to be more sustainable than ever. But how about the construction industry? Instead, a linear approach - design, build, demolish - can buildings be recycled? or adaptive reuse? Maybe all these passive measures are not enough in this revolutionary area to echol, the circular economy concept, architecture design in the 21st century need to move one step further to create spaces that evolve alongside with this fast-changing world, allow its programs to adjust for future use.
Moreover, under the influence of circular economy concept, new generation consumers prefer access over ownership; such trend can be seen in a pervasive growth of services such as Zipcar,Ubike and more in the past decade. Such mindset is not only changing the landscape of commercial products and service but also challenging the concept of homeownership in most metropolitan areas in the world. Nowadays issues of an aging society and the vanishing of the middle class start to challenge people’s perception about homeownership and their way of living. In Netherland, Germany, and Japan, the idea of collective living begin to take shape. Government funded housing projects that encourage young people and senior citizens to live collectively have started to gain momentum in these countries. perhaps such collective housing projects pro-vide a basis for us, as architects, in envisioning future residential spaces. Taiwan and Japan share some similarity in social challenges, since above social challenges already occurred in Japan, perhaps it’s a perfect time for us to be innovated and design a new type of residential space that reflects 21-century consumer behavior and social issues we are facing.
19
20
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
GLOBAL ISSUES? CLIMATE CHANGE? GLOBALIZATION? OVERPOPULATION? POVERTY? ENVIRONMENTAL POLLUTION? DISEASE? TERRORISM?
21 CENTURY NEW SOCIAL HOUSING AND NEW LIFE STYLE
BECAUSE OF THE ADVANCEMENT OF TECHNOLOGY AND MEDICAL CARE ......
21
SUPER AGED SOCIETY ELDERS PROBLEM
WORLD POPULATION ISSUE SUPER AGED SOCITY As early as 1993, the proportion of elderly people in Taiwan reached 7%, making it an “aging” society. This rate is expected to reach 14% by 2018, when it will become an “aged” society. By 2025, more than 20% of the population will cross the threshold, making Taiwan a “super-aged” society, where one in every five people will be elderly.
[ TFR , TAIWAN ]
[ TOTAL POPULATION , TAIWAN ]
[ POPULATION (AGE 20~64) , TAIWAN ]
[ POPULATION (AGE 65+) , TAIWAN ]
22
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
DEGREE OF AGING
It is estimated that in 2061, 45 years from now, “old-age dependency ratio”will surge to 81.4%, when every 1.2 young adults will need to bear the weight of one elderly person, such that the ratio will be close to 1:1.
23
E CHIANG VILLAG KUO SHUEN VILLAGELIN8.0% CHING HSIANG VILLAGE 8.4%
8.4%
IN THE CASE OF TAIWAN, ITS AGEING INDEX IS 92%. BUT FROM THE EVIDENCE, TAIWAN’S RATE OF AGEING IS LIKE AN UNSTOPPABLE TRAIN, WITH THE SPEED SURPASSING THAT OF ANY DEVELOPED COUNTRY.
WORLD TOTAL FERTILITY & LIFE EXPECTANCY Every country in the world is currently facing the problem of an aging population, but the issue is particularly serious in developed countries, due to prolonged life expectancy and a reduced birth rate. This can be seen from the “aging index”, that is the proportion of the population aged 65 or above divided by the population under the age of 14. The higher the index, the more serious is the extent of aging. taiwan’s fertility will less than 1.5 in 2025.
It is estimated that in 2061, 45 years from now, this will surge to 81.4% when every 1.2 young adults will need to bear the weight of one elderly person, such that the ratio will be close to 1:1. In recent years, the life expectancy of the people of Taiwan has been increasing annually. in 2015, the national average was 80.2 years old, with males at 77.01 years old and females at 83.62 years old.
About 35 years ago, Taiwan's “old-age dependency ratio” was 6.9%, meaning that every 14.5 young adults needed to support one elderly person. However, this figure had more than doubled to 16.2% by 2014, meaning that every 6.2 young adults needed to care for one elderly person.
[ 2050~2055 ] 24
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
THE AGED SOCIETY
25
Datong DISTRICT, Taipei
HISTORICAL MAP
[ QING DYNASTY (1850) ] [ JAPANESE COLONIAL PERIOD (1920) ]
[ NOW (2010) ]
Datong DISTRICT SITE
Datong thrived in the early 1900s when the Dadaocheng wharf emerged as Taipei's main stop for boats bringing rice down the Danshui river. Now, as the kilometre-long Dihua street, at the district's core, comes back to life, coffee houses, craft shops and art galleries are springing up alongside stores still run by the families that established them. "This is a living old street," Redevelopment is claiming the northern half of dihua street, but the city requires that new structures resemble those that they are replacing and storekeepers from other parts of the city like what they are seeing.
3 KM
26
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
ADAPTABLE HOUSING BY COMBINING THE CONTAINER SYSTEM WITH THE ORIGINAL LIVING UNIT. TAKE OFF ALL WALLS IN THE UNIT, REPLACE THEM WITH FURNITURES LIKE CABINET OR TABLE. WITH OUT WALLS, THE HOUSE CAN ADAPT MOST OF SISUATION A FAMILY WILL MEET. IF FAMILY MEMBERS CHANGE, THE UNIT CAN ALSO INCREASE OR REDUCE THE SPACE TO SOLVE THE PROBLEM. BECAUSE OF THE CONTAINER STRUCTURE SYSTEM, THE ELEVATION OF UNIT CAN BE CHANGE EASILY BY THE OWNER THEMSELVES.
ONE ADULT
YOUNTH YOUNG ADULT SINGLE
ONE ADULT + ONE KID
ONE ADULT + TWO KIDS
NUCLEAR FAMILY (ONE ADULT)
ONE�PARENT FAMILY �ONE KID�
ONE�PARENT FAMILY �TWO KIDS�
NUCLEAR FAMILY (ONE TEENAGER) ONE�PARENT FAMILY �TWO TEENAGERS�
TWO ADULTS
FOUR ADULTS
TWO ADULTS + ONE KID
TWO ADULTS + TWO KIDS
COHABITING COUPLE
NUCLEAR FAMILY (TWO TEENAGERS)
NUCLEAR FAMILY (ONE KID)
NUCLEAR FAMILY (TWO KIDS)
DINK FAMILY COUPLE ONE�PARENT FAMILY �ONE TEENAGER� ONE�PARENT FAMILY �ONE ADULT�
27
THREE ADULTS
HOUSING UNIT STUDY The principal aim in the design of the house has been to reduce carbon emissions by providing a flexible and functional layout. This means that:
TYPE C
TYPE A
THE COMPONENTS OF THE HOUSE CAN BE DISMANTLED, AND THE HOUSE CAN BE EXPANDED WITHOUT DESTROYING EXISTING COMPONENTS.
TYPE B
THE REPLACED COMPONENTS CAN BE REUSED IN NEW CONTEXTS. THE COMPONENTS ARE FABRICATED IN STANDARD SIZES AND FROM STANDARD MATERIALS.
COUPLE
TYPE A
ONE-PARENT FAMILY (ONE TEENAGER) ONE-PARENT FAMILY (ONE ADULT)
YOUNG ADULT
TYPE A + TYPE B
ONE-PARENT FAMILY (TWO TEENAGERS)
TYPE A + TYPE C
NUCLEAR FAMILY (ONE KID) ONE-PARENT FAMILY (TWO KIDS)
SINGLE NUCLEAR FAMILY (ONE ADULT)
ONE-PARENT FAMILY (ONE KID) NUCLEAR FAMILY (TWO TEENAGERS)
YOUNTH
NUCLEAR FAMILY (ONE TEENAGER) COHABITING COUPLE
TYPE A + TYPE B +TYPE C
DINK FAMILY
28
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
THE PLAZA CONNECT ALL ACTIVIES IN THE BUILDING.
A HOUSING SHOULD SUPPORT A PERSON’S WHOLE LIFE, NOT JUST A PART OF IT ......
THE POOL IS IN FOURTH FLOOR, IT PROVIDE THREE KINDS OF ACTIVITIES AND CREATES ENTERACE FOR THE BUILDING.
29
A - A’ SECTION
30
2015-2019 PORTFOLIO OF JCC / EA3_3 21 CENTURY SOCIAL HOUSING
HOUSING PLAN
1
1
2
3
4
5
1
2
3
4
5
6
A
A
B
2
1 3
4
5
6
A 5
B
3
4
5
6
A
B
9
2
6
B 15
1 C
C
3 4
D
C
7
11
10
6
2
D
C
12
D
14 16
D
8 13
1. KINDERGARDEN 2. LOBBY 3. COFFEE SHOP 4. PLAZA
FIRST FLOOR PLAN 0
1
2
2 4
6
10
14
(M)
5. COMPUTER SPACE 6. GYM 7. BAR 8. WEWORK SPACE 9. YOGA SPACE 10. CINEMA
SECOND FLOOR PLAN 0
1 3
4
5
2
6
10
14
(M)
11. COMMUNITY KITCHEN 12. MEP 13. STORAGE
3
4
5
B
2 4
6
10
(M)
0
1 3
4
5
2
2 4
6
10
3
4
3
4
5
0
3
4
5
6
10
14
(M)
6
B
C
(M)
0
2
2 4
6
10
EIGHTH FLOOR PLAN 14
(M)
0
1 3
4
5
6
B
2
3
4
2 4
6
10
14
5
6
A
(M)
6
A
B
B
C
D
2 4
5
6
SEVENTH FLOOR PLAN 14
C
D
FOURTH FLOOR PLAN
2
D
A
B
14. BAR 15. SWIMMING POOL 16. SHOWER
A
1
6
A
C
(M)
1
SIXTH FLOOR PLAN 14
14
D
FIFTH FLOOR PLAN 0
10
C
D
2
6
B
B
1
2 4
A
C
D
0
2
6
A
C
THIRD FLOOR PLAN
1
6
A
2 4
18
C
D
D 17 18 19
NINTH FLOOR PLAN 0
31
2 4
6
10
TENTH FLOOR PLAN 14
(M)
0
2 4
6
10
ELEVENTH FLOOR PLAN 14
(M)
0
2 4
6
10
14
(M)
17. SECURITY 18. DUMING FILL 19.MEP
BASEMENT FLOOR PLAN 0
2 4
6
10
14
(M)
MODEL PHOTOS
32
2015-2019 PORTFOLIO OF JCC / EA4_1 INTERACTIVE PNEUMATIC INSTALLATION
+ ADAPTABILITY + INFLATABLE CONTROL + SKIN & STRUCTURE + MODULE SYSTEM
2015-2019 PORTFOLIO OF JCC / EA4_1 INTERACTIVE PNEUMATIC INSTALLATION
INTERACTIVE PNEUMATIC INSTALLATION The imagination and cognition of the pneumatic device are generally used to occupy a certain proportion in space after being filled, or creating a unique atmosphere. So when I got the subject, I started to study the potential that the pneumatic device can be controlled. At first, I think about the various possibilities of the development unit in an individual way, then discuss the relationship between the units. I hope that I can develop a device that can be conntrolled by inflation.
AADRL – Behavioural Complexity; Mobile, Self-Aware and Self-Assemble - XO
AADRL – Behavioural Complexity; Mobile, Self-Aware and Self-Assemble - OWO
ADAPTIVE PNEUMATIC SHELTERS HANI FALLAHA
ADAPTIVE PNEUMATICS
AA INTERPROFESSIONAL STUDIO - SEED TO SCENE
SOLDERCUBES
35
UNIT IDEA
\ ROD \ AIRBAG \ ELASTIC ROPE \ INFLATION %
\ ROD \ AIRBAG \ SPRING \ EXTEND
\ ROD \ AIRBAG \ RUBBER BAND \ OPEN
36
2015-2019 PORTFOLIO OF JCC / EA4_1 INTERACTIVE PNEUMATIC INSTALLATION
RODS ARRANGEMENT \ PARTS RODS AND AIRBAG \ FINAL SHAPE PNEUMATIC \ STRIP AIRBAG ELASTIC ROPE \ SPRING STRENTH ELASTIC ROPE PATH \ STRAGGERED.STRAGIHT INFLAT FROM \ CORNER.MIDDLE
UNIT STUDY
\ SURFACE \ GRID SYSTEM
After choosing which kind of inflatable unit to use, I started a series of various attempts.
TEST 1 / DIFFERENT ROPE PATH
INFLAT FROM CORNER . STAGGERED ROPE PATH \ 5-PARTS . 3-PARTS
TEST 2 / ROPE PATH ON BOTH SIDE(SURFACE)
3-PARTS . STRAIGHT ROPE PATH \ INFLAT FROM MIDDLE . CORNER
5-PARTS . CORNER . STAGGERED ROPE PATH HADR TO INFLAT 0%~100% \ CONTROLLABLE
[ TEST MODEL ] 3-PARTS . MIDDLE . STRAIGHT ROPE PATH EASY TO INFLAT 0%~100% \ CHANGE OBVIOUSLY 37
A
B A
TEST 3 / NEW AIRBAG TYPE (PENTAGON)
B
UNIT PROTOTYPE
RODS AND AIRBAG \ FINAL SHAPE
After the experiment is completed, four methods that can cause prototype change are sorted out.
ELASTIC ROPE PATH \ STRAGGERED.STRAGIHT
CHANGING \ BEND
CHANGING \ POLYGON
[ PROTOTYPE MODEL ]
38
2015-2019 PORTFOLIO OF JCC / EA4_1 INTERACTIVE PNEUMATIC INSTALLATION
MDOEL_1 Study the shallow force that the pneumatic device can be controlled First think about the various possibilities of the development unit in an individual way, then discuss the relationship between the units. I hope that I can control the whole device by inflation.
DIVIDING LINE ELASTIC ROPE ROD
UNIT A UNROLL SCALE: 1:2
The reason I chose the hexagonal column as my unit prototype is that it is easier and more variable in the combination of the units. Also because of the obtuse that I don't have too many restrictions when I operate the rod. Limit airbag inflation and increase control points by arranging rigid rods on the airbag.Use elastic wires to connect the rods to change the state before the airbag is inflated. CONNECT UNIT
INDEPENDENT UNIT
The purpose of making this model is to try to discuss the relationship between the groups in a practical way. And with the 1:1 production, you can find some problems in the actual manufacturing level that cannot be found in the small model.
39
The shape of the airbag before inflation is limited by the rod and the elastic rope.When the airbag is inflated, the elastic rope can be pulled apart.The shape of the airbag will tend to look like there is no elastic rope. As soon as stops inflating, because the tension of the elastic rope, airbag will return to the originally restricted state. The main discussion on the unit is that the rods, elastic ropes and airbags take turns to serve as bones or cortex in different stages of inflation.They are mutually restrained and support each other.I hope to use this study to control the shape change of a single unit.
MDOEL_1
UNIT B
UNIT W
UNIT C
UNIT D
UNIT X
UNIT E
UNIT F
UNIT Y
UNIT G
UNIT Z
UNIT B
UNIT C
UNIT D
UNIT E
UNIT F
CHANGING / BEND RODS ARRANGING STRAIHGT ROPE PATH
CHANGING / BEND RODS ARRANGING STRAIHGT ROPE PATH
CHANGING / EXTEND RODS ARRANGING STRAGGERED ROPE PATH OPPOSITE ORDER
CHANGING / EXTEND RODS ARRANGING STRAIHGT ROPE PATH
CHANGING / BEND RODS ARRANGING STRAIHGT ROPE PATH
UNIT G
UNIT W
UNIT X
UNIT Y
UNIT Z
CHANGING / BEND RODS ARRANGING STRAGGERED ROPE PATH
CHANGING / BEND RODS ARRANGING STRAGGERED ROPE PATH RODS ON TWO FACES
CHANGING / BEND RODS ARRANGING STRAIHGT ROPE PATH
CHANGING / ROTATE RODS ARRANGING ROPE CROSS OVER FACES
CHANGING / NONE
40
2015-2019 PORTFOLIO OF JCC / EA4_1 INTERACTIVE PNEUMATIC INSTALLATION
MDOEL_2
[ TWO POINT PEOSPECTIVE ]
DIVIDING LINE ROD
ELASTIC ROPE SCALE: 1:4
The purpose of making this model is to try to discuss the relationship between the groups in a practical way. And with the 1:1 production, you can find some problems in the actual manufacturing level that cannot be found in the small model. [ TOP VIEW ] 41
[ SIDE VIEW ]
CONCLUTION The reason I chose the hexagonal column as my unit prototype is that it is easier and more variable in the combination of the units. Also because of the obtusethat I don't have too many restrictions when I operate the rod. Limit airbag inflation and increase control points by arranging rigid rods on the airbag.Use elastic wires to connect the rods to change the state before the airbag is inflated. The shape of the airbag before inflation is limited by the rod and the elastic rope.When the airbag is inflated, the elastic rope can be pulled apart.The shape of the airbag will tend to look like there is no elastic rope.As soon as stops inflating, because the tension of the elastic rope, airbag will return to the originally restricted state.The main discussion on the unit is that the rods, elastic ropes and airbags take turns to serve as bones or cortex in different stages of inflation.They are mutually restrained and support each other.I hope to use this study to control the shape change of a single unit.
[ MODEL_1 ]
It’s a failure in the entire design experiment. There are several reasons for this: In making an inflatable unit that is completely leak-proof, it may be too difficult for the technology I currently have.Because the air leak caused the entire design to have insufficient support to stand alone. In order to make it stand up, and can change shape due to inflation, I keep trying to shrink the whole, and finally show my ideal results slightly.
[ MODEL_2 ]
[ MODEL_2 ] 42
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
+ WOOD + FREE-FORM SURFACE + PARAMETRIC + FEBRICATION
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
CONCEPT_1 SKELTON & INTER LOCKING THE SKELETON SYSTEM IS THE MOST COMMON AND STABLE STRUCTURAL SYSTEM. ALL SURFACES CAN BE ALMOST COMPLETED THROUGH THE DISTRIBUTION OF WARP AND WEFT STRUCTURES. THE DENSITY OF THE STRUCTURE WILL ALSO DIRECTLY EFFECT THE STRUCTURAL STRENGTH OF THE SURFACE..
SURFACE
170.47°
90°
Z Y
X
SURFACE DRAWING LATITUDE UNITS
RENDER DRAWING
NUMBERS OF UNITS: 9
THE MOST STABLE AND SIMPLEST WAY TO CONSTRUCT A SURFACE
LONGITUDE UNITS CONTROL THE PARABOLIC OF THE SURFACE
LATITUDE UNITS DECIDE THE SECTOR ANGLE AND BEING THE JOINT BETWEEN LONGITUDE UNITS
VERTICAL UNITS
90
300
LONGITUDE UNITS NUMBERS OF UNITS: 2
240
720
SURFACE CONSTRUCTION: SKELTON
(mm)
MATERIAL: WOOD MATERIAL TYPE: LUMBER(6MM)
GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: Z↑60MM DIVIDE SURFACE: U=1 V=10 SECTOR ANGEL: 9.53°
BECAUSE OF MANUFACTURING REASONS THE CONNECTED PART BETWEEN THE WARP AND WEFT UNITS MUST BE VERTICAL
TOP VIEW DRAWING
DIVIDE SURFACE INTO 10 EQUAL SEGEMENTS
FRONT VIEW DRAWING
THE CASSETTE SYSTEM MAINLY COMPLETES THE SURFACE THROUGH THE ANGLE OF THE CASSETTE ON THE UNIT. THE SYSTEM IS SIMPLE AND INTUITIVE. YOU CAN INCREASE THE STRUCTURAL STRENGTH OF THE SYSTEM BY DESIGNING MORE THAN ONE UNIT.
SURFACE
Z Y
X
SURFACE DRAWING
HORIZONTAL UNITS
RENDER DRAWING
NUMBERS OF UNITS: 22
NUMBERS OF UNITS: 12
BEING THE JOINT BETWEEN HORIZONTAL UNITS
LATITUDE UNITS DECIDE THE SECTOR ANGLE
IT IS A EASY WAY TO CONSTRUCT A SURFACE BUT DUE TO SOME MANUFACITRING REASONS THE MODEL NEED SUPPORT TO STAY STABLE
90
300 240
720
SURFACE CONSTRUCTION: INTER LOCKING
(mm)
MATERIAL: WOOD MATERIAL TYPE: LUMBER(6MM)
GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: Z↑+-12.5MM DIVIDE SURFACE: HORIZONTAL UNITS U=1 ; VERTICAL UNITS U=4 V=12 V=36 SECTOR ANGEL: 9.53°
45
DIVIDE SURFACE INTO 144 EQUAL SEGEMENTS CONSTRUCT THE VERTICAL UNITS FROM SURFACES’ VERTICES
INTER LOCKING DRAWING IT SHOWS HOW THE LATCH WORK
DIVIDE SURFACE INTO 12 EQUAL SEGEMENTS OFFSET 10MM ON SURFACE TO CONSTRUCT THE HORIZONTAL UNTS
FRONT VIEW DRAWING VERTICAL UNITS THE PARABOLIC OF THE SURFACE
SOLDERCUBES
CONCEPT_1 LATTICE & RECIPROCAL LATTICE SYSTEM IS A UNIT CONNECTION COMBINATION. FINISHING THE SURFACE BY DESIGNING A GEOMETRIC LATTICE UNIT. THE DISTRIBUTION OF THE LATTICE IS SIMILAR TO THE NETWORK STRUCTURE. IT IS POSSIBLE TO HAVE DIFFERENT SIZES OF LATTICE UNITS SIMULTANEOUSLY ON A CURVED SURFACE.
SURFACE
Z Y
X
SURFACE DRAWING A UNITS
B UNITS
RENDER DRAWING
NUMBERS OF UNITS: 6
NUMBERS OF UNITS: 10
IT IS THE ONLY CONSTRUCT SYSTEM THAT IS STILL STABLE AFTER REMOVE SOME UNITS
90
300 240
720
(mm)
SURFACE CONSTRUCTION: LATTICE
MATERIAL: WOOD MATERIAL TYPE: LUMBER(6MM)
GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: Z↑40MM DIVIDE SURFACE: A UNITS U=2 ; B UNITS U=2 V=8 V=13 SECTOR ANGEL: 9.53°
DIVIDE SURFACE INTO 16 AND 26 EQUAL SEGEMENTS WEAVING HALF OF THEM TOGETHER
PERSPECTVE DRAWING ORIGINAL FORM
REMOVE SOME UNITS TO SHOW HOW LATTICE SYSTEM WORK
FRONT VIEW DRAWING EACH LATTICE IS A BOX AND CONNECTED WITH OTHERS BY LATCH
THE RECIPROCAL SYSTEM IS THE MOST COMPLEX SYSTEM IN STRUCTURE. THE ENTIRE STRUCTURAL SYSTEM IS MAINTAINED IN AN EQUILIBRIUM STATE BY SIMILAR LEVERAGE PRINCIPLE BETWEEN UNITS. USUALLY PAY ATTENTION TO CERTAIN ORDER AND LOGIC WHEN ASSEMBLING UNITS.
SURFACE
Z Y
X
SURFACE DRAWING
ODD UNITS
EVEN UNITS
RENDER DRAWING
NUMBERS OF UNITS: 4
NUMBERS OF UNITS: 3
THE MOST DIFFICULT WAY TO CONSTRUCT A SURFACE THERE IS TOO MANY THINGS THAT AFFECT THE CONSTRUCTION SUCH AS: CURVATURE, MATERIAL THICKNESS, LATCH...
90
300 240
720
SURFACE CONSTRUCTION: RECIPROCAL GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: 0MM DIVIDE SURFACE: U=1 V=8 SECTOR ANGEL: 9.53°
(mm)
MATERIAL: WOOD MATERIAL TYPE: LUMBER(6MM)
DIVIDE SURFACE INTO 8 EQUAL SEGEMENTS CONSTRUCT THE UNITS FROM SURFACES’ VERTICES
PERSPECTVE DRAWING ORIGINAL FORM
ONLY ONE KIND OF UNIT
FRONT VIEW DRAWING LUMBER THICKNESS EFFECT THE PARABOLIC
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2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
CONCEPT_2 SKELTON & BENDING / WEAVING & RECIPROCAL COMPLETE THE CURVATURE OF THE SURFACE BY BENDING THE PIECE OF WOOD. WOOD CHIP AS LONGITUDE UNIT. THEN COMPLETE THE SURFACE WITH OTHER WOOD CHIPS CONNECTED TO THE LONGITUDE UNIT.
SURFACE
Z Y
X
SURFACE DRAWING
LONGITUDE UNITS
RENDER DRAWING
NUMBERS OF UNITS: 5 LATITUDE UNITS DECIDE THE SECTOR ANGLE AND BEING THE JOINT BETWEEN LONGITUDE UNITS
THE MOST STABLE AND SIMPLEST WAY TO CONSTRUCT A SURFACE BUT WITH THE MATERIAL’S ELASTICITY, IT BECOME HARD TO CONTROL
ODD UNITS
EVEN UNITS
RENDER DRAWING
NUMBERS OF UNITS: 4
NUMBERS OF UNITS: 3
BECAUSE VENEER IS TOO THIN(1MM) TO HOLD IT SELF SO IT NEED SUPPORT TO CONSTRUCT THE SURFACE
180
405
LATITUDE UNITS
NUMBERS OF UNITS: 3 LONGITUDE UNITS CONTROL THE PARABOLIC OF THE SURFACE (GLUED MOLDING)
240
720
SURFACE CONSTRUCTION: SKELTON & BENDING
(mm)
MATERIAL: WOOD MATERIAL TYPE: VENEER(1MM)
GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: 0MM DIVIDE SURFACE: U=5 V=13 SECTOR ANGEL: 18°
DIVIDE SURFACE INTO 65 EQUAL SEGEMENTS
TOP VIEW DRAWING
SELCET ISOTRIM SURFACES INTO UNITS
FRONT VIEW DRAWING
DESIGN THE UNIT BY THE CHARACTERISTICS OF THE WOOD PIECE THAT CAN BE BENT. LET THE UNITS BE WOVEN TOGETHER AND THEN COMPLETE THE SURFACE THROUGH THE BASE.
SURFACE
Z Y
X
SURFACE DRAWING BEING THE JOINT BETWEEN ODD UNITS BECAUSE OF MATERIAL’S ELASTICITY, ITS CAN WEAVE UNITS TOGETHER
180
405 240
720
SURFACE CONSTRUCTION: WEAVING & RECIPROCAL
(mm)
MATERIAL: WOOD MATERIAL TYPE: VENEER(6MM)
GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: 0MM DIVIDE SURFACE: EVEN UNITS U=3 ; ODD UNITS U=4 V=7 V=7 SECTOR ANGEL: 18°
47
DIVIDE SURFACE INTO 21 AND 28 EQUAL SEGEMENTS
TOP VIEW DRAWING EVEN AND ODD UNIT ARE WEEAING TOGETHER
SELCET ISOTRIM SURFACES INTO UNITS
FRONT VIEW DRAWING IT IS KIND LIKE RECIPROCAL
CONCEPT_2 WEAVING & INTER LOCKING & BENDING / LATTICE & BENDING BY DESIGNING THE CURVED PIECE OF WOOD AND THEN COMBINING THEM TO COMPLETE THE SURFACE. CAN DESIGN DIFFERENT CURVATURE UNITS TO RESPOND TO DIFFERENT SURFACES.
SURFACE
Z Y
X
SURFACE DRAWING EVEN UNITS
RENDER DRAWING
NUMBERS OF UNITS: 12
NUMBERS OF UNITS: 16
BECAUSE THE LATCH ON UNITS ARE HARD TO CONTROL SO IT NEED SUPPORT TO STAND
ODD UNITS
EVEN UNITS
RENDER DRAWING
NUMBERS OF UNITS: 11
NUMBERS OF UNITS: 10
BECAUSE OF THE MATERIAL’S ELASTICITY, IT BECOME HARD TO CONTROL IT’S NEED SUPPORT TO STAND
180
405
ODD UNITS
Z =10 Y =12
X =40 (mm)
240
720
(mm)
SURFACE CONSTRUCTION: MATERIAL: WOOD WEAVING & INTER LOCKING & BENDING MATERIAL TYPE: VENEER(6MM) GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: Z↑30MM DIVIDE SURFACE: EVEN UNITS U=4 ; ODD UNITS U=3 V=8 V=8 SECTOR ANGEL: 18°
DIVIDE SURFACE INTO 24 AND 32 EQUAL SEGEMENTS WEAVING HALF OF THEM TOGETHER
TOP VIEW DRAWING EVEN AND ODD UNIT ARE WEEAING TOGETHER
UNIT TO DO BOX MORPH
FRONT VIEW DRAWING EACH UNITS IS CONNECTED WITH OTHERS BY LATCH
BY DESIGNING CURVED LATTICE WOOD CHIP UNITS AND THEN COMBINING THEM TO COMPLETE THE SURFACE. BECAUSE THE DESIGN OF THE CIRCULAR UNIT CAN BE ELASTICALLY MATCHED TO THE BASE TO PRODUCE CURVED SURFACES WITH DIFFERENT CURVATURES.
SURFACE
Z Y
SURFACE DRAWING
UNIT
270
607.5
(mm)
SURFACE CONSTRUCTION: LATTICE & BENDING GEOMETRY TYPE: PARABOLIC ARCH SURFACE EXTRUDE: Z↑20MM DIVIDE SURFACE: U=3 V=7 SECTOR ANGEL: 26.72 °
X
R=18 r=15 H=10
MATERIAL: WOOD MATERIAL TYPE: VENEER(6MM)
(mm)
DIVIDE SURFACE INTO 21 EQUAL SEGEMENTS
TOP VIEW DRAEING
SEPRATE UNITS INTO EVEN AND ODD UNITS ONLY ONE KIND OF UNIT
FRONT VIEW DRAWING
48
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
SITE SITE: HUISUN FOREDT AREA HUISUN FOREST AREA IS ALSO USED AS A SIGHTSEEING SPOT AND EXPERIMENTAL FOREST FARM OF THE UNIVERSITY. I CAN MAKE A CONCEPTUAL, EXPERIMENTAL DESIGN WITH WOOD HERE.
49
HUISUN EXPERIMENTAL FOREST FARM HUISUN EXPERIMENTAL FOREST FARM IS AN EXPERIMENTAL FOREST FARM AFFILIATED TO NATIONAL CHUNG HSING UNIVERSITY. IT IS ONE OF THE FOUR EXPERIMENTAL FOREST FARMS OF THE SCHOOL WITH AN AREA OF 7,477 HECTARES. FROM 450 METERS TO 2,419 METERS ABOVE SEA LEVEL, IT HAS DIFFERENT CLIMATIC CHARACTERISTICS SUCH AS SUBTROPICAL AND TEMPERATE CLIMATE.
50
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
EDUCATION OBSERVATORY_PLAN
PROGRAM: OBSERVATORY CONCEPT: SKELTON, INTER LOCKING, BENDING AREA: 144.06 M^2 HEIGHT: 11.76 M USE: ACADEMIC 51
PLAN
EDUCATION OBSERVATORY_SIDE VIEW DRAWING
52
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
EDUCATION OBSERVATORY_DETAIL THE SITE IS LOCATED ON A VIEWING PLATFORM IN THE FARM. ADD ANOTHER PLATFORM ON THE ORIGINAL ONE INORDER TO LET STUDENTS GAIN MORE CLEAR VIEW HERE.
METAL PILLARS & CABLES
THE DESIGN IS DIVIDED INTO TWO PARTS: THE TOP LAYER AND BOTTOM PLATFORM. THE UPPER AND LOWER PARTS ARE INTERTWINED TO CREATE A TWISTED FEELING. VENEER FACADE
UNITS PRODUCTION
MEATL BEAMS & TRUSSES
LASER CUTTING
BENDING
WOOD PLANK
CONNECTION BETWEEN FACADE & BEAMS
WOODEN BEAM VENEER BEAM
METAL BEAMS
[ EXPLOSIVE DRAWING ] 53
EDUCATION OBSERVATORY_RENDERIGN
54
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
PAVILION - CAMPING AREA_PLAN
PROGRAM: PAVILION CONCEPT: LATTICE, BENDING AREA: 98.67 M^2 HEIGHT: 4.60 M USE: MORE TOURISM 55
PLAN
PAVILION - CAMPING AREA_SIDE VIEW DRAWING
56
2015-2019 PORTFOLIO OF JCC / EA4_2 VENEER FREE-FORM SHELL WEAVING FABRICATION
PAVILION - CAMPING AREA_DETAIL THE SITE IS LOCATED AT A CAMPING AREA INSIDE THE FARM. BECAUSE THERE ARE A LOTS OF TREES HERE, SO MANY TOURISTS LIKE TO USE HAMMOCKS HERE. AT THE BEGINNING OF THIS DESIGN, I WAS TRYING TO CREATE ARESPOND TO THE TREE. I HOPE TO BUILD A PAVILION IN THE WOODS. PERIPHERAL FIXATION FACADE UNITS
PERIPHERAL FIXATION THE CONNECTION WITH TREE NUT THREADED ROD
5MM*5MM WOODEN STICK
NUT
FACADE UNITS
CONNECTION BETWEEN UNITS
BENDING VENEER
METAL SUPPORT
SCREW
BENDING VENEER
WOODEN BASE
[ EXPLOSIVE DRAWING ] 57
PAVILION - CAMPING AREA_RENDERIGN
58
2015-2019 PORTFOLIO OF JCC / EA1_SUMMER BUBBLE FARM
+ AGRICULTURE + WOOD + MODULE SYSTEM + 1;1
BUBBLE FARM Agriculture is essential to human prosperity and it is still the most important factor in the future of human existence, as a lack of sustainable agriculture industry system may cause obstacles to humans' future. This study contests that Aquaponic farming could provide the needed agriculture component for urban farming, as it can be easily adopted for urban conditions and be commanded by the users. Aguaponic farming reduces the use of chemical fertilizers and the waste of water resources by redefining the relationship between humans and agriculture and how it can become part of the urbanscape.
1
2
6
3
5
2
5
6 6
1 2
5 4
3
4 1
3
1
2
4 1
3
2
6
4 1 6
2
5 4 1
2 5 4
4 1
2
5
3
4 1 6 4
2
2
3 6
5
4 1
4 1
2
3 6
5
2
3 5 4 2
5 4 2 1
3
5 4 2
3 6 2
5
3
1 3 6
4 1
3 6
5
4 1
3 6
6
5
3 6
5
2
3 6
2
3 6
5 2
5
4 1
5 4 1 2
1
3 6
5
2
6
4 1 6
1 6
1
6
3 5
4
3 5
4
3
60
2015-2019 PORTFOLIO OF JCC / EA3_SUMMER & EA4_SUMMER DIGITAL AIEOU
+ RHINO + GRASSHOPPER + ROBOT + CLAY & METAL + FUN
SOLDERCUBES
DIGITAL AIEOU_ROBOT ARM WORKSHOP
TKUA CAAD
TKUA CAAD
2018 Robot Arm Workshop Robotic Arm Offline Programming & Digital Fabrication
Clay Printing Group Phase 1: SD
Team 3
Members: CHUN-CHUAN, LO YUNG-CHUN, SHIH
2019 Robot Arm Workshop
2019
Robotic Arm Offline Programming & Digital Fabrication
Rod Bending Group Phase 1: SD
A.Final
Team
Members:羅浚銓/游子毅/林思妤
A.
B. Unit 1
Unit 2
Unit 3
Unit 4
Phase 2: Robotic Simulation
Move
Scale
Rotate
Point connect
Phase 2: Parametric Modeling
A.Final
B.
Conversion process
Top
Front
Right
Detail
Perspective
Phase 3: Robotic Fabrication
Phase 3: Robotic Fabrication
Phase 3: Rendering & Final Modeling
Phase 4: Rendering & Final Modeling
62