he last nights, let me try to describe it:-disclaimer: I'm an industrial designer, my coding experience can be compared to your, when you were 4 year old :)-disclaimer 2: I did a picture at the end of the post that maybe explains more than my words
the component has 2 inputs (Start Value, End Value) and one output (Picked Value)
this phantomatic component (which I would refere to as "dynamic value picker") supports any amount of domains on every input -> it works as if they come grafted, from a "longest list" component
The component "at rest" shows only one slider -with question marks on both edges-
For every couple on inputs you connect (1 Start Value connection + 1 End Value connection) it would visually generate a new slider (exactly like a "number slider" component)main difference from the "number slider" component, this one would show the Start Value and End Value numbers at the edges of each thus generated slider
Right click -> edit on it would recall a window similar to the "number slider", with the main difference that only the first part of those options would be present (see attached image for clarity)Whatever slide accuracy you set, it will affect the whole "dinamic value picker" phantom component (if you set "integer numbers" and for any reason one or more inputs are "floating points numbers", the component automatically rounds the inputs to the best "Integer", and allows you only to pick integer numbers in-between)
If you suddenly change a "Start Value" or an "End Value" input, the affected slider/sliders in the component will try to stay as close as possible to the same % value they were before (example if the domain was from 5 to 11, integers only, and you first picked the value 8, the slider was exactly in position 50%: when you change the End Value domain to 21 the slider will set itself to 13 - yes, I picked an easy one lol )
When you first plug a couple of Start Value + End Value, the slider sets itself to Picked Value = Start Value
It could also be possible to supply negative values as Value End and positive values as Value Start: the slider let you pick a number on that domain regardless of the numerical order you use
Last thing, but it's just fancy imagination, if you zoom-in the output (Picked Value) connection dot, a little - and + appears (like in other common components), letting you add a new cursor to every existing slider (it could be possible to customize the color of the new cursor to avoid confusion)
This is the exact description of what I would ask to the lamp genie :)
I attach a pic I just did, in the hope to better explain myself: picture link
and of course thank you again for reading this long poem!
…
g-in, brief theory of complex systems, introduction to multi-agent systems and non-linear design, flocking, Boid library, basic examples - brownian motion, adhesion, separation, alignment, geometry following.-----------------------TIME: first session10am – GMT, London11am – Paris, Brussels, Rome, Vienna, Budapest, Bratislava, Warsaw9pm - Sidney7pm – Tokyo6pm – Beijing, Shanghai, Shenzhen, Hong Kong, Taipei3:30pm – Mumbai3pm – Karachi2pm - Samara1pm – Baghdad, Moscow, St Petersburg12pm – Istanbul, Athens, Helsinki, Cairo, JohannesburgTIME: second session3pm – GMT, London4pm – Paris, Brussels, Rome, Vienna, Budapest, Bratislava, Warsaw7pm – Dubai, Abu Dhabi, Baku6:30pm – Tehran6pm – Baghdad, Moscow, St Petersburg5pm – Istanbul, Athens, Helsinki, Cairo, Johannesburg1pm – Rio de Janeiro, São Paulo, Montevideo12pm – Buenos Aires, Santiago10am – Toronto, New York City, Bogota, Lima9am – Mexico City7am – Los AngelesWEBINARSThe rese arch Grasshopper® sessions are unique for their thorough explanation of all the features, which creates a sound foundation for your further individual development or direct use in the practice. The webinars are divided into four groups: Essential, Advanced, Iterative and Architectural. If you are a Rhinoceros 3D or Grasshopper® newcomer, you are advised to take all the Essential sessions before proceeding to the next level. If none of the proposed topics suit your needs or if you require special treatment, you can request a custom-tailored 1on1 session. All sessions are held entirely in English.The webinars are series of on-line live courses for people all over the world. The tutor broadcasts the screen of his computer along with his voice to the connected spectators who can ask questions and comment in real time. This makes webinars similar to live workshops and superior to tutorials.…
Added by Jan Pernecky at 3:36pm on February 17, 2015
as one element.
Thank you
Comment by karamba on October 7, 2014 at 11:27pm
Hello Patricio, divide the beams in such a way that each boundary vertex of the shell becomes an endpoint of a beam segment.
Best, Clemens
Comment by Llordella Patricio on October 8, 2014 at 8:30amDelete Comment
Hi Clemens,
I did what you suggested but now assemble element doesn´t work properly. Could you please tell me how to fix it? Thanks in advance, Patricio
8-10-14losa%20cadena.gh
Comment by karamba on October 8, 2014 at 11:59am
Hi Patricio, if you flatten the 'Elem'-input at the 'Assemble'-component the definition works. The triangular shell elements have linear displacement interpolations whereas the beam deflections are exact. In order to get correct results you should refine the shell mesh.
Best, Clemens
Comment by Llordella Patricio on October 9, 2014 at 8:35amDelete Comment
Hello, succeeds in creating the mesh to the slab, and built the beam segment, but when I see the deformations are not expected because the beam is deformed as the slab.
Thanks for the help
PS: maybe I'm using the program for a type of structure that is not the most appropriate, as I saw in the examples of other structures. But this type of structure is that students taught
best regards
Patricio
9-10-14%20Example%201.gh
Comment by karamba on October 9, 2014 at 10:46am
You could use the 'Mesh Edges'-component to retrieve the naked edges and turn them into beams - see attached file:91014Example1_cp.gh
Best regards,
Clemens
Comment by Llordella Patricio on October 15, 2014 at 3:41pmDelete Comment
Dear clemens
I was doing a rough estimate of the deformation, and I can not achieve the same result with Karamba. When I make a rough estimate of the result with Karamba beams and mine are very similar, I think the problem is when I connect the shell, because there are no similar results.
I sent the GH file, and an image of the calculation
The structure is concrete The result I get is 0.58cm
thank youPatricio
15-10-14%20Example.gh
Comment by karamba yesterday
Dear Patricio,
try to increase the number of shell elements. As mentioned in the manual they are linear elements. A mesh that is too coarse leads to a response which is stiffer than the real structure.
Best,
Clemens
…
hops, design sessions & symposia across 5 cities in India. We encourage all architecture & design students and professionals to join us in this novel experimentation event and aid in 'Filling The Void'; Void in Architecture, Void in our Cities, Void in Education. REGISTRATIONS ARE OPEN NOW.
rat[LAB] Computational Design Tour - INDIA
Agenda // Filling The Void
1 country // 5 cities // 1 agenda // 100+ students // 25+ professionals // 5 exhibitions // 1 publication
Void is typically defined as null, invalid, empty or redundant and has a psychological perception of a ‘negative’. Through years of development in India, there has been an organic urban growth and inorganic architectural growth which has led to formation of voids in a physical and a metaphorical sense. There also exist voids as gaps between architecture, cities, education and technology. ‘Filling The Void’ looks at void as an opportunity, potential and a driver of change for architecture & design education in India.
// Cities & Dates*
Mumbai – 22nd June to 24th June 2015 (Monday to Wednesday)
Chennai - 29th June to 1st July 2015 (Monday to Wednesday)
Bengaluru – 3rd July to 5th July 2015 (Friday to Sunday)
Chandigarh - 16th July to 18th July 2015 (Thursday to Saturday)
New Delhi – 6th August to 8th August 2015 (Thursday to Saturday)
*Venue details are published on rat[LAB] website.
// Registration Dates
// Early-bird Registrations Open: 08 May 2015
// EXTENDED Early-bird registrations End: 05 June 2015
// General Registrations End: 15 June 2015 (Or till seats last)
…
ly fabricated interventions and interactive electronic performance art installations in Barra Funda. Along with other experts, these tutors will teach how to use and apply new design technologies, notably Rhino and Grasshopper (and numerous plug-ins including GECO, Galapagos, Kangaroo and RhinoCam); Arduino and Processing; and the use of laser-cutters, rapid- prototype machines and CNC routers and mills.
Alan Dempsey of NEX, was in 2010, selected by the Centre for European Architecture/Chicago Athenaeum as one of the 40 most significant architects in the EU under 40. In 2008 he was selected by the British Council as one of the six most significant Design Entrepreneurs. He previously worked with Future Systems, OCEAN and Homa Farjadi. Alan was an AA Unit Tutor and is Director of the AA Independent’s Group (www.independentsgroup.net), which facilitates research into the use of computational design and fabrication. Alan has lectured, exhibited and been published worldwide. His work has received a number of awards, including a LEAF award for Spencer Dock Bridge, and a D&AD pencil for the [C]space DRL 10 Pavilion.
Robert Stuart Smith of Kokkugiais a Studio Course Master at the AA DRL. Robert previously worked for Lab Architecture Studio and Nicholas Grimshaw & Partners. He focuses on self-organisational systems and developmental growth, pursuing polyvalent and environmentally responsive affect. He leads consultation to Cecil Balmond on non-linear algorithmic design research. Kokkugia has projects in the USA, UK and Mexico, and is exhibited and published internationally.
Iván Ivanoff is an artist, programmer, and researcher. He searches for new forms of communication for the society of the future and is the director of different Media Labs worldwide. He founded the artistic collaborative i2off.org+r3nder.net, which develops multi-media and interactive projects, and Estado Lateral Media Lab to investigate and develop new technologies.
The Barra Funda district of São Paulo was once characterised by a mix of small industrial, commercial and residential programmes, but, as economic policies have favoured larger production industries, numerous companies have abandoned the area. In response, the workshop proposes the creation of new types of smaller industries to produce a mix of both consumption and production, manifested through micro-manufacturing interventions that can co-exist alongside retail and housing. Computational design and digital fabrication could be used to help create these new micro-industries, which in turn will help empower local craftsman to produce and sell directly to consumers through micro-manufacturing, located in small urban workshops.
The workshop will tap into emergent gallery scene of Barra Funda and local initiatives that use computational technology to introduce a new cultural and economic impetus. The workshop is a part of the International Festival of Electronic Language (FILE), an exhibition of interactive electronic technology, and will import these electronic technologies out of the galler, collaborating with local manufacturers, artists, and activists, with a goal of disseminating a high-tech yet low-cost and small-scale fabrication systems to promote this new micro-industrial movement. The workshop is open to architecture and design students and professionals worldwide.…
f objects with the main ring body, and that cannot be done in parallel since you are modifying the item once at a time, algorithmically.
The original example of a cylinder and sphere are textbook failures of the Rhino 5 dumb algorithm, since that combination features kissing surfaces that confuse Rhino about where they are intersecting since really in tolerance values they are overlapping along a ribbon instead of a sharp line.
Normally you would slightly move or rescale one of the pair to create a single loop intersection curve that doesn't wander around in jerky fashion trying to combine two surfaces that fail to actually plunge through one another.
Your main Boolean union is 116 prongs with a ring base, and that's slow because Rhino bogs down as the model gets more an more complicated with each internal step, I imagine.
The speed is not all that slow either, only 21 seconds for the Booleans themselves.
If you turn of Grasshopper preview meshing via the toolbar menu it should be significantly faster while you are tweaking the design.
To troubleshoot the slow Boolean, I went into Rhino and tried merely splitting the ring body with the prongs and that itself was just about as slow as the Boolean union, so Rhino is not being badass about it. Then I exploded the ring body and tried splitting just that with the prongs and it was *much* faster to operate on just that single surface! The black box reveals itself a bit.
In kind, splitting the prongs with that single surface was about the same speed as splitting it with the whole ring body, so no speed gain there.
But, to speed up your script, since we *cannot* in fact use parallel processing, we can instead manually create that prong surface by doing our own splits and using Grasshopper's natural order of parts, hopefully consistent, to get rid of the junk.
That prong surface is item 4 of an exploded object.
So I will mutually split them and tease out the good parts from the junk and then rejoin the parts, no Boolean union component needed.
First, I went into your prong cluster and removed the capping, so I have merely an open revolution surface instead of a polysurface, letting me access the surface trim command after quickly finding the BrepBrep intersection curves between the prongs and the single ring surface.
For that Boolean union step I'm down from 11 seconds to 4 seconds, but confusingly we added a second to the Boolean difference that follows:
It's fast since we are manually selecting junk instead of Rhino having to sort which is which, I imagine.
We still have a slow Boolean subtraction of the gems and holes from the finished ring body.
That's not simple so will remain slow and cannot be parallel processed since again there's a single main ring body being modified in each step, and nor are there simple pairs of split object to select from manually to discard junk.
…
quired)
// Agenda
Parametric Design, in the history of architecture, has defined many rules for current designers and for future practitioners to follow. One of the strongest aspects that are prominent from this style is ‘geometry’. Arguably, there is nothing new about geometry and aesthetics forming the most prominent aspect of any style or era. The language of any style, in the long history of architecture, is visually defined by geometry or shape, beyond the principles that define the core of the style. In the distinguishable style of parametric architecture, geometry has played and is continuing to play an integral role. And with this fairly young style, there are many strings of myths and false notions associated.
The workshop aims to provide a detailed insight to ‘parametric design’ and embedded logics behind it through a series of design explorations using Rhinoceros & Grasshopper platforms, along with understanding of data-driven fabrication strategies. An insight to Computational Design and its subsets of Parametric Design, Algorithmic Design, Generative Design and Evolutionary Design will be provided through presentations, technical sessions & studio work, with highlighting agenda of using data into Hands-on fabrication of a parametrically generated design. A strong focus will be made on ‘geometry’ and ‘matter’.
Day 1 Topics / Agenda
Rhinoceros 3D GUI and basic use
Installing Grasshopper & plug-ins
Grasshopper GUI
Basic logic, components, parameters, inputs, numbers, simple geometry, referenced geometry, locally defined geometry, baking, etc.
Lists & Data Tree: management, manipulation, visualization, etc.
Design Experimentations with Geometry & Data
Understanding Data for Manual Fabrication
Day 2 Topics / Agenda
Design Experimentations with Geometry, Form, Matter
Data for effective numbering and strategizing during Manual Fabrication
Collaborative effort for Hands-on ‘making’ process
Analysis & Evaluation of Fabricated Geometry
Documentation
// Tutor(s): Sushant Verma (Architect / Computational Designer / Educator)
…
way of setting the camera in grasshopper to get the camera in the Top Viewport?
EDIT: Seems to be a real problem for me
Hi guys,
Love the work! Please would you consider adding a function to the horster camera components that makes them only work on a user specified viewport. That way I can have a definition set up for the Perspective Viewport and it not mess up the others when they go active.
Many thanks,
Danny
Tags: Wish, getCamera, viewport
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Replies to This Discussion
Permalink Reply by Jacek Markusiewicz on August 24, 2011 at 10:25am
sure i will. thanks for the comment!!
EDIT: all the three set camera components I have got to know today are onle working in the perspective viewport
…
ly 26-27-28-29 (digital fabrication)
The third edition of digitalMed Workshop is structured as a design laboratory. Participants will learn the challenging process of producing ideas, projects and research analysis that are to be developed through specific software and concepts that emerge through the use of mapping, parametric design and digital fabrication.
The workshop will take place in the city of Salerno (Italy) and it will last 11 days structured into 3 intensive weekends: July 13-14-15 (mapping); July 19-20-21-22 (parametric design); July 26-27-28-29 (digital fabrication).
Goals and Objectives:
We aim to make clear the theoretical and technical knowledge in the approach to parametric and generative design and digital fabrication. (From collection and data management, to the manner in which these inform the geometries, to the fabrication of prototypes.)
Participants will also have the opportunity to practice the new knowledge gained in the design laboratory through project work.
Project Theme:
"Urban Field" Identify, study and analyze the system of public spaces in the urban area of the city of Salerno.
Connection, mutation, generation and evolution are the themes to be followed in project work.
Brief Description of Topics:
- Mapping. Our reality, in all its forms, has studied through concepts of the theory of Complex Systems. The techniques that will be used to study events and places of reality, will work for the management, manipulation and visualization of data and information. These will form the basis for project management and driven geometry, conducted during the second phase of the workshop.
- Parametric Design. Introduction to Rhino* and Grasshopper. Specifically, we will explain the concepts with which to work with the software of parametric design and how they function. Through these tools, we will arrive at the definition of systems of mathematical and / or geometrical relationships that are able to generate and govern patterns, shapes and objects that will inform the final design.
- Digital Fabrication. In this phase, participants of the workshop are organized into working groups. Participants have access to materials and conceptual apparatus that will take them directly to the fabrication of the geometries of the project, with the use of software CAD / CAM interface and the use of machines for the digital fabrication.
The DigitalMed workshop is organized by Nomad AREA (Academy of Research & Training in topics of Contemporary Architecture), in collaboration with the City of Salerno, the Order of Architects Province of Salerno and the National Institute of Architecture In / Arch - Campania.
Interested parties may download the Notice of Competition at the address www.digitalmedworkshop.com and fill the pre-registration no later than July 10th 2012.
PRESS OFFICE
Dr. Francesca Luciano
328 61 20 830
fra_luciano@libero.it
For information or subscriptions:
e-mail: info@digitalmedworkshop.com - tel: 089 463126 - 3391542980 …
1 JUN to 31 DECBetween hours 1:00 to 24:00Current document units is in MetersConversion to Meters will be applied = 1.000[1 of 7] Writing simulation parameters...Ground temperature data contains monthly average temperatures at 3 different depths .5 meters (1st)2 meters (2nd)4meters (3rd)respectively[2 of 6] No context surfaces...[3 of 6] Writing geometry...[4 of 6] Writing materials and constructions...[5 of 7] Writing schedules...[6 of 7] Writing loads and ideal air system...[7 of 7] Writing outputs......... idf file is successfully written to : c:\ladybug\unnamed\EnergyPlus\unnamed.idf
Analysis is running!...c:\ladybug\unnamed\EnergyPlus\eplusout.csv......
Done! Read below for errors and warnings:
Program Version,EnergyPlus, Version 8.3.0-6d97d074ea, YMD=2015.05.24 11:32,IDD_Version 8.3.0
** Warning ** IP: Note -- Some missing fields have been filled with defaults. See the audit output file for details.
** Warning ** Version: in IDF="'8.1.0'" not the same as expected="8.3"
************* Beginning Zone Sizing Calculations
** Severe ** GetSurfaceData: Some Outward Facing angles of subsurfaces differ significantly from base surface.
** ~~~ ** ...use Output:Diagnostics,DisplayExtraWarnings; to show more details on individual surfaces.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=AW0 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=AW0 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=AW0 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=AW0 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=AW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=AW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=AW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=AW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=AW2 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=AW2 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=AW2 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=AW2 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=AW3 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=AW3 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=EW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=EW1 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=GLZ_0_EW1_1F6383543B434F648813 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=0.9038)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=GLZ_0_EW1_1F6383543B434F648813 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=0.9038)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=GLZ_0_EW1_1F6383543B434F648813 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=16.0967)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=GLZ_0_EW1_1F6383543B434F648813 is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=16.0967)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 6 of back surface=FLOOR is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 7 of back surface=FLOOR is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 8 of back surface=FLOOR is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 9 of back surface=FLOOR is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 5 of back surface=CIELING is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 6 of back surface=CIELING is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=17.1101)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 7 of back surface=CIELING is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 8 of back surface=CIELING is in front of receiving surface=EW0
** ~~~ ** (Dot Product indicator=30.0900)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=AW6 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=AW6 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=WALLW1 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=WALLW1 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=WALLW1 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=WALLW1 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=GLZ_0_WALLW1_103854D39BEF453D8A4E is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=GLZ_0_WALLW1_103854D39BEF453D8A4E is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=GLZ_0_WALLW1_103854D39BEF453D8A4E is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=GLZ_0_WALLW1_103854D39BEF453D8A4E is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=EW0 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=EW0 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=GLZ_0_EW0_6AEDE94222384E5B8950 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=1.4709)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=GLZ_0_EW0_6AEDE94222384E5B8950 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=1.4709)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=GLZ_0_EW0_6AEDE94222384E5B8950 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=15.6696)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 4 of back surface=GLZ_0_EW0_6AEDE94222384E5B8950 is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=15.6696)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 1 of back surface=FLOOR is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=FLOOR is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 2 of back surface=CIELING is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Severe ** Problem in interior solar distribution calculation (CHKBKS)
** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone="APRATMENT1"
** ~~~ ** because vertex 3 of back surface=CIELING is in front of receiving surface=EW1
** ~~~ ** (Dot Product indicator=17.0963)
** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.
** Warning ** ManageSizing: For a plant sizing run, there must be at least 1 Sizing:Plant object input. SimulationControl Plant Sizing option ignored.
************* Testing Individual Branch Integrity
************* All Branches passed integrity testing
************* Testing Individual Supply Air Path Integrity
************* All Supply Air Paths passed integrity testing
************* Testing Individual Return Air Path Integrity
************* All Return Air Paths passed integrity testing
************* No node connection errors were found.
************* Beginning Simulation
************* Simulation Error Summary *************
** Warning ** The following Report Variables were requested but not generated
** ~~~ ** because IDF did not contain these elements or misspelled variable name -- check .rdd file
************* Key=*, VarName=ZONE PACKAGED TERMINAL HEAT PUMP TOTAL COOLING ENERGY, Frequency=Hourly
************* Key=*, VarName=ZONE PACKAGED TERMINAL HEAT PUMP TOTAL HEATING ENERGY, Frequency=Hourly
************* Key=*, VarName=CHILLER ELECTRIC ENERGY, Frequency=Hourly
************* Key=*, VarName=BOILER HEATING ENERGY, Frequency=Hourly
************* Key=*, VarName=FAN ELECTRIC ENERGY, Frequency=Hourly
************* Key=*, VarName=ZONE VENTILATION FAN ELECTRIC ENERGY, Frequency=Hourly
************* Key=*, VarName=ZONE VENTILATION TOTAL HEAT LOSS ENERGY, Frequency=Hourly
************* Key=*, VarName=ZONE VENTILATION TOTAL HEAT GAIN ENERGY, Frequency=Hourly
************* There are 1 unused schedules in input.
************* There are 1 unused week schedules in input.
************* There are 3 unused day schedules in input.
************* Use Output:Diagnostics,DisplayUnusedSchedules; to see them.
************* EnergyPlus Warmup Error Summary. During Warmup: 0 Warning; 0 Severe Errors.
************* EnergyPlus Sizing Error Summary. During Sizing: 1 Warning; 49 Severe Errors.
************* EnergyPlus Completed Successfully-- 4 Warning; 49 Severe Errors; Elapsed Time=00hr 00min 4.59sec
Thanks Abraham.I really appreciate it.
Another thing ' I posted a discussion few days ago and got no replies.And this forum is the only 'Hope' for me..Can you quickly check it?thanks.
N
http://www.grasshopper3d.com/group/ladybug/forum/topics/free-form-external-wall-with-glazing-workflow?xg_source=activity
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