large scale prototyping techniques. The programme continues to build on its expertise on complex architectural design and fabrication processes, relying heavily on materiality and performance. Autumn DLAB brings together a range of experts – tutors and lecturers – from internationally acclaimed academic institutions and practices, Architectural Association, Zaha Hadid Architects, among others.
The research generated at Autumn DLAB has been published in international media – ArchDaily, Archinect, Bustler – and peer-reviewed conference papers, including SimAUD (Simulation in Architecture and Urban Design), eCAADe (Education and research in Computer Aided Architectural Design in Europe).
Autumn DLAB investigates on the correlations between form, material, and structure through the rigorous implementation of computational methods for design, analysis, and fabrication, coupled with analog modes of physical experimentation and prototype making. Each cycle of the programme devises custom-made architectural processes through the creation of novel associations between conventional and contemporary design and fabrication techniques. The research culminates in the design and fabrication of a one-to-one scale prototype realized by the use of robotic fabrication techniques, with the aim of integrating of form-finding, material computation, and structural performance.
The programme is structured in two stages:
PART 1 – participants are introduced to core concepts of material processes, computational methods and digital fabrication techniques. Basic and advanced tutorials on computational design and analysis tools are provided. The programme performs as a team-based workshop promoting collaboration, research and ‘learning-by-experimentation’.
PART 2 – participants propose design interventions based on the skills and knowledge gained during phase 1 and supported by scaled study models and prototypes. The fabrication and assembly of a full-scale architectural intervention with the use of robotic fabrication techniques will then unify the design goals of the programme.
Applications
1) A limited number of 10 places are available. To apply, please send a small portfolio (5MB) to the Visiting School Office.2) PARTIAL SCHOLARSHIPS ARE AVAILABLE. Please send a letter of intent and a small portfolio (5MB) to the Visiting School Office.3) As this programme has a limited number of places it requires a selection process, if you are offered a place on programme, the Visiting School Office will inform you of how you can complete the registration process.
The deadline for applications is 13 AUGUST 2021.
Eligibility
The workshop is open to current architecture and design students, PhD candidates and young professionals. Software Requirements: Adobe Creative Suite, Rhino 6. No prior knowledge of software tools is required for eligibility.
Fees
The AA Visiting School requires a fee of £975 per participant, which includes a £60 Digital Membership fee.Students need to bring their own laptops, digital equipment and model making tools.
…
he "return" is comment out as shown below?
After restarting Rhino and Grasshopper, I opened the outdoors_airflow demo file, and the first step of creating the case file is ok:
Then the blockMesh component gives the following error: seems I have to manually start OF first..
so, as the error message suggested, I open OF by Start_OF.bat:
Then come back to the blockMesh component, now it can be executed while the OF command line window is also openning:
... and the blockMesh finished successfully:
... so I proceeded to run snappyHexMesh, checkMesh and update fvScheme:
... up to the simpleFoam component, I got the error again:
The warning message is:
1. Solution exception: --> OpenFOAM command Failed!#0 Foam::error::printStack(Foam::Ostream&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #1 Foam::sigFpe::sigHandler(int) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #2 ? in "/lib64/libc.so.6" #3 double Foam::sumProd<double>(Foam::UList<double> const&, Foam::UList<double> const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #4 Foam::PCG::solve(Foam::Field<double>&, Foam::Field<double> const&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #5 Foam::GAMGSolver::solveCoarsestLevel(Foam::Field<double>&, Foam::Field<double> const&) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #6 Foam::GAMGSolver::Vcycle(Foam::PtrList<Foam::lduMatrix::smoother> const&, Foam::Field<double>&, Foam::Field<double> const&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::Field<double>&, Foam::PtrList<Foam::Field<double> >&, Foam::PtrList<Foam::Field<double> >&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #7 Foam::GAMGSolver::solve(Foam::Field<double>&, Foam::Field<double> const&, unsigned char) const in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libOpenFOAM.so" #8 Foam::fvMatrix<double>::solveSegregated(Foam::dictionary const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/lib/libfiniteVolume.so" #9 Foam::fvMatrix<double>::solve(Foam::dictionary const&) in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #10 Foam::fvMatrix<double>::solve() in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #11 ? in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam" #12 __libc_start_main in "/lib64/libc.so.6" #13 ? in "/opt/OpenFOAM/OpenFOAM-v1606+/platforms/linux64GccDPInt32Opt/bin/simpleFoam"
... and the command lines in the readMe! output are pretty long and it is saved in the text file attached here.
So, my questions are:
1. why I have to manually start OF first before I can use the blockMesh component? Should butterfly automatically start OF?
2. what might be the cause of the unsuccessful run of simpleFoam in the end?
Hope you can kindly advise! Thank you!
- Ji
…
ion y fabricación en un mismo proceso.
Para este taller se han seleccionado un conjunto de técnicas y estrategias para resolver problemas que hoy se presentan en el diseño y fabricación digital de formas complejas y euclidianas.
Bajo dos entornos de trabajo, entre técnicas interactivas y soluciones algorítmicas, se examinan conceptos y casos de estudio que le permitirán al participante decidir como y en que momento estas tecnologías pueden ser utilizadas como aliadas en los procesos de diseño y fabricación. Tomando como plataforma básica Rhino, se explora y optimiza el diseño y fabricación de topologías complejas bajo los entornos de Grasshopper, RhinoNest y RhinoCam.
En el mes de Febrero de 2010 (23 al 26 de febrero) se realizará el Workshop D.O.F Diseño-Optimizacion-Fabricacion en McNeel Argentina,
Está abierto para todas las personas y al participar obtendrás una licencia de Rhino 4.0.
Para hacer el workshop se requiere un conocimiento basico de Rhino 3.0 o 4.0
Contenidos:
1. Modelado Avanzado y sus Tecnicas. Aplanado y Desarrollo de Superficies.Anidado y distribución Nesting.
2. Introducción al Diseño Paramétrico.Definiciones Avanzadas de Grasshopper,posibilidades y limitaciones. Ajustes de escala para impresión y corte.
3. Introducción a la Manufactura en CNC - RhinoCAM 2.0. Visita al laboratorio CAM.
4. Guía Paso a Paso para la realización de un Renderizado usando Brazil 2.0. Presentación DIGITAL de proyectos.
El workshop tiene una duracion de 32 hrs. (4 dias x 8 horas por dia, horario 9 a 13 hrs y 15 a 19hrs)
Docentes
Andres Gonzalez Posada - McNeel Miami. - Grasshopper - RhinoCAM - RhinoNest
Facundo Miri - McNeel Argentina - Brazil for Rhino.
Se dictara en McNeel Argentina
Ciudad de la paz 2719 3A. - Belgrano - Capital Federal.
Costo del Curso
U$S250+IVA Curso D-O-F SIN entrega de licencia de Rhino 4
U$S350+IVA Curso D-O-F con entrega de licencia de RHino 4 Educativa (solo para docentes y estudiantes).- Precio de la licencia sola U$S195
U$S995+IVA Curso D-O-F con entrega de licencia de Rhino 4 Comercial. (profesionales y empresas) - Precio de la licencia sola U$S995
Contactos:
Facundo Miri
Facundo Miri (54-011) 4547-3458
facundo@mcneel.com
McNeel Argentina
Robert McNeel & Associates
McNeel Seattle - Miami - Buenos Aires
Ciudad de la Paz 2719 3A
www.rhino3d.TV - www.rhinofablab.com
Las personas interesadas pueden llamar al 4547-3458 o enviar mail a facundo@mcneel.com
Quienes esten fuera de la ciudad podran hacer un deposito bancario (solicitar datos de la cuenta por mail) y enviar por mail el comprobante de deposito con siguientes datos:
Nombres completos - DNI - Fecha de Nacimiento - Teléfono fijo - Celular - Correo Electrónico.
Muchas Gracias
You can find the prices at: http://www.rhino3d.com/sales/order-la.htm just click on the "Commercial" o "Student" tab.…
Added by Facundo Miri at 1:10pm on December 10, 2009
e técnicas avanzadas de modelación 3d y su fabricación digital (corte láser e impresión 3d). Se utilizara Rhinoceros y Grasshopper, no es necesario tener conocimiento previo de los programas, únicamente manipular algún programa CAD.
Fechas:
Miercoles 13: 18:30 a 22:30Jueves 14: 18:30 a 22:30Viernes 15: 18:30 a 22:30Sábado 16: 11:00 a 14:30 y de 15:30 a 21:00Domingo 15: 11:00 a 14:30 y de 15:30 a 21:00
Fecha límite de Pago: lunes 11 de Junio del 2012Estudiantes: $160.000Profesionales: $220.00
Descuento para integrantes de Makerspace del 40% (5 cupos únicamente)
Importante:
Todos los niveles de experiencia son bienvenidos el único requisito es tener un entendimiento básico de los programas CAD y una actitud positiva hacia el aprendizaje de dichas herramientas. Necesitas llevar una laptop, nosotros te instalamos los programas de prueba.
Si planeas venir de fuera de la ciudad avísanos y te pondremos en contacto con otras personas que también vayan a hacerlo para en caso de desearlo puedan compartir su lugar de estancia.
Al participar en el workshop obtienes el 50 % de descuento en la licencia educacional Rhinoceros por medio de Rhino Chile.
Proceso de Inscripción:
El participante deberá pagar la matrícula haciendo un depósito bancario a la cuenta que aparece a continuación.
Banco: Estado
Nombre: Luis de la Parra Galván
No. Cuenta: 00169946655
Para obtener los datos restantes para hacer una transferencia o depósito mandar un mail a info@chidostudio.com
El depósito mínimo para reservar la matrícula es del 50% el resto deberá ser cubierto el día del evento.
Una vez que el depósito se haya llevado a cabo el participante deberá enviar a este correo info@chidostudio.com los siguientes datos:
Nombre completo
Email
Teléfono
Institución educativa u Oficina
Archivo adjunto del recibo del depósito bancario
En cuanto recibamos la información immediatamente nos pondremos en contacto para especificar los pasos a seguir.
Contacto Santiago [Sede]
Luis de la Parra
Cel: 714-660-33
info@chidostudio.com
http://www.facebook.com/Chidostudio
Todos los mails se responden en un máximo de 24 horas.
Muchas gracias por tu interés saludos…
rring to the above image)
Area
effective
effective
Second
Elastic
Elastic
Plastic
Radius
Second
Elastic
Plastic
Radius
of
Vy shear
Vz shear
Moment
Modulus
Modulus
Modulus
of
Moment
Modulus
Modulus
of
Section
Area
Area
of Area
upper
lower
Gyration
of Area
Gyration
(strong axis)
(strong axis)
(strong axis)
(strong axis)
(strong axis)
(weak axis)
(weak axis)
(weak axis)
(weak axis)
A
Ay
Az
Iy
Wy
Wy
Wply
i_y
Iz
Wz
Wplz
i_z
cm2
cm2
cm2
cm4
cm3
cm3
cm3
cm
cm4
cm3
cm3
cm
I have a very similar table which I could import to the Karamba table. But I have i_v or i_u values as well as radius of inertia for instance.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
dimensjon
Masse
Areal
akse
Ix
Wpx
ix
akse
Iy
Wpy
iy
akse
Iv
Wpv
iv
Width
Thickness
Radius R
[kg/m]
[mm2]
[mm4]
[mm3]
[mm]
[mm4]
[mm3]
[mm]
[mm4]
[mm3]
[mm]
[mm]
[mm]
[mm]
L 20x3
0.89
113
x-x
4,000
290
5.9
y-y
4,000
290
5.9
v-v
1,700
200
3.9
20
3
4
L 20x4
1.15
146
x-x
5,000
360
5.8
y-y
5,000
360
5.8
v-v
2,200
240
3.8
20
4
4
L 25x3
1.12
143
x-x
8,200
460
7.6
y-y
8,200
460
7.6
v-v
3,400
330
4.9
25
3
4
L 25x4
1.46
186
x-x
10,300
590
7.4
y-y
10,300
590
7.4
v-v
4,300
400
4.8
25
4
4
L 30x3
1.37
175
x-x
14,600
680
9.1
y-y
14,600
680
9.1
v-v
6,100
510
5.9
30
3
5
L 30x4
1.79
228
x-x
18,400
870
9.0
y-y
18,400
870
9.0
v-v
7,700
620
5.8
30
4
5
L 36x3
1.66
211
x-x
25,800
990
11.1
y-y
25,800
990
11.1
v-v
10,700
760
7.1
36
3
5
L 36x4
2.16
276
x-x
32,900
1,280
10.9
y-y
32,900
1,280
10.9
v-v
13,700
930
7.0
36
4
5
L 36x5
2.65
338
x-x
39,500
1,560
10.8
y-y
39,500
1,560
10.8
v-v
16,500
1,090
7.0
36
5
5
I have diagonals (bracings) which can buckle in these "non-regular" directions too, and they do. If I could add those values then in the Karamba model I could assign specific buckling scenarios..... I can see another challenge which will be at the ModifyElement component, I will not be able to choose these buckling lengths, in these directions.
Do you think this functionality can be added within short, or should I try to find another way to model these members?
Br, Balazs
…
Introduction to Grasshopper Videos by David Rutten.
Wondering how to get started with Grasshopper? Look no further. Spend an some time with the creator of Grasshopper, David Rutten, to learn the
nts for Ladybug too. They are based on PVWatts v1 online calculator, supporting crystalline silicon fixed tilt photovoltaics.
You can download them from here, or use the Update Ladbybug component instead. If you take the first option, after downloading check if .ghuser files are blocked (right click -> "Properties" and select "Unblock").
You can download the example files from here.
Video tutorials will follow in the coming period.
In the very essence these components help you answer the question: "How much energy can my roof, building facade, solar parking... generate if I would populate them with PV panels"?
They allow definition of different types of losses (snow, age, shading...) which may affect your PV system:
And can find its optimal tilt and orientation:
Or analyse its performance, energy value, consumption, emissions...
By Djordje Spasic and Jason Sensibaugh, with invaluable support of Dr. Frank Vignola, Dr. Jason M. Keith, Paul Gilman, Chris Mackey, Mostapha Sadeghipour Roudsari, Niraj Palsule, Joseph Cunningham and Christopher Weiss.
Thank you for reading, and hope you will enjoy using the components!
EDIT: From march 27 2017, Ladybug Photovoltaics components support thin-film modules as well.
References:
1) System losses:
PVWatts v5 Manual, Dobos, NREL, 2014
2) Sun postion equations by Michalsky (1988):
SAM Photovoltaic Model Technical Reference, Gilman, NREL, 2014
edited by Jason Sensibaugh
3) Angle of incidence for fixed arrays:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
4) Plane-of-Array diffuse irradiance by Perez 1990 algorithm:
PVPMC Sandia National Laboratories
SAM Photovoltaic Model Technical Reference, Gilman, NREL, 2014
5) Sandia PV Array Performance Module Cover:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
6) Sandia Thermal Model, Module Temperature and Cell Temperature Models:
Photovoltaic Array Performance Model, King, Boys, Kratochvill, Sandia National Laboratories, 2004
7) CEC Module Model: Maximum power voltage and Maximum power current from:
Exact analytical solutions of the parameters of real solar cells using Lambert W-function, Jain, Kapoor, Solar Energy Materials and Solar Cells, V81 2004, P269–277
8) PVFORM version 3.3 adapted Module and Inverter Models:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
9) Sunpath diagram shading:
Using sun path charts to estimate the effects of shading on PV arrays, Frank Vignola, University of Oregon, 2004
Instruction manual for the Solar Pathfinder, Solar Pathfinder TM, 2008
10) Tilt and orientation factor:
Application for Purchased Systems Oregon Department of Energy
solmetric.com
11) Photovoltaics performance metrics:
Solar PV system performance assessment guideline, Honda, Lechner, Raju, Tolich, Mokri, San Jose state university, 2012
CACHE Modules on Energy in the Curriculum Solar Energy, Keith, Palsule, Mississippi State University
Inventory of Carbon & Energy (ICE) Version 2.0, Hammond, Jones, SERT University of Bath, 2011
The Energy Return on Energy Investment (EROI) of Photovoltaics: Methodology and Comparisons with Fossil Fuel Life Cycles, Raugei, Fullana-i-Palmer, Fthenakis, Elsevier Vol 45, Jun 2012
12) Calculating albedo: Metenorm 6 Handbook part II: Theory, Meteotest 2007
13) Magnetic declination:
Geomag 0.9.2015, Christopher Weiss…