KURT9000: 2016

2016年11月8日星期二

Digital Building Lab | Auto-routing Test

Project Description |

In ship design and chip design, auto-routing is a common technology to deal with highly complex routing problem. However, routing can be viewed as a broader technology to help architects design circulations and deal with piping problem. This program is the first take trying to search all the possible routing solutions. The computation is very expensive, so it can work in a small region for now.

Fig.01 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.02 - Routing solution with 3 sets of points, 0 obstacle in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.03 - Routing analysis with 3 sets of points, 0 obstacle in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.04 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.05 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.06 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.07 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.08 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.09 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.10 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Fig.11 - Routing solution with 4 sets of points, 2 obstacles in a 6 x 6 box, T.C. Kurt Hong, 2016 Summer

Shape Computing Group | Froebel Blocks

Project Description |

For shape grammar 101, Froebel Blocks are always a good tool to help us understand shape grammar. However, Froebel Blocks are physical tools which has some limitations that students can hardly use as many blocks as they can. Also, physical Froebel Blocks limit some possible combinations because physical blocks can not overlap to each other (embedded in each other). Thus, this project is aimed to develop a digital tool which can expand the educational possibilities of Froebel Blocks. This program is developed in Rhino environment with Rhino Python.

Fig.01 - 5-rule Combination Analysis, T.C. Kurt Hong, 2016 Summer

Fig.02 - 5 rules, T.C. Kurt Hong, 2016 Summer

Fig.03 - 5-rule Combination 3, T.C. Kurt Hong, 2016 Summer

Shape Computing Group | Emergence SHAPE

Project Description |

This project is aimed to develop a graph engine which can recognize emergence shapes according to the concept of shape grammar by George Stiny in 1960's. "Shape" is a non-classical representation which provide readers multiple ways to read. For human beings, it is easy to catch a sub-shape embedded in a shape but difficult to computers. The first version of this engine is designed to find out all the quadrilaterals including convex ones and concave ones. This engine is developed in Rhino environment with Rhino Python to connect architecture designers. Users can draw any shape and this engine will report the number of all possible quadrilaterals and list them as a category.

Fig.01 "Finding all quadrilaterals" Test 01, T.C. Kurt Hong, 2016 Summer

Fig.02 "Finding all quadrilaterals" Test 02, T.C. Kurt Hong, 2016 Summer

Fig.03 "Finding all quadrilaterals" Test 03, T.C. Kurt Hong, 2016 Summer

Fig.04 "Finding all quadrilaterals" Test 04, T.C. Kurt Hong, 2016 Summer

Fig.05 "Finding all quadrilaterals" Test 05, T.C. Kurt Hong, 2016 Summer

Fig.06 "Finding all quadrilaterals" Test 06, T.C. Kurt Hong, 2016 Summer

2016年5月10日星期二

Capstone - Folding Concrete

Folding Concrete Review - T.C. Kurt Hong, Z.J. Candice Yang, 2016 Winter

Folding Concrete Model 3 - T.C. Kurt Hong, Z.J. Candice Yang, 2016 Winter

Molds - T.C. Kurt Hong, Z.J. Candice Yang, 2016 Winter

Casting Process - T.C. Kurt Hong, Z.J. Candice Yang, 2016 Winter

2016年3月2日星期三

Capstone | Folding Concrete

Test Folding Concrete, T.C. Kurt Hong & Candice Yang, Winter 2016

Details, T.C. Kurt Hong & Candice Yang, Winter 2016

Test Molds, T.C. Kurt Hong & Candice Yang, Winter 2016

Casting Process, T.C. Kurt Hong & Candice Yang, Winter 2016

Demolding, T.C. Kurt Hong & Candice Yang, Winter 2016

Details, T.C. Kurt Hong & Candice Yang, Winter 2016

Test Folding Concrete, T.C. Kurt Hong & Candice Yang, Winter 2016

Capstone | Wall

Project |

From hotwire cutting, we established the molds for our bricks. Every brick can be aggregated up and create voids. By shifting the middle pieces of the molds, we can create different bricks, in other words, the mold can be seen as a reconfigurable mold.

Wall, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Void in the Wall, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Brick 1, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Bricks 4 & 5, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Casting Brick 4, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Casting "Brick 1", T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Casting "Brick 5", T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Test Wall, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

Molds, T.C. Kurt Hong & Amogha Krishnaiah, Winter 2016

2016年1月20日星期三

Capstone | Hot wire cutting

Project |

The goal of this project is to develop advanced technics for concrete precasting. In the beginning of capstone, we are required to practice using hot wire cutting foams. By cutting foams, complex frameworks can be produced for casting concrete. The hot wire cutter is mounted on a small robot, KUKA KR6. Hot wire cutting is easy to use and can create complex curvature surfaces. Besides using hot wire, the design goal is to make a wall which can be assembled with many components.