Loft is connecting circles on her\his arbitrary way, not counting the wireframe wich is made from Crvs from points.
Like a wireframe in a picture with a last def. from you, such exact Surface I need. Maybe some sweep rail, where a every 2 circles are Rail and a arc (trough 3 point) or segment of interCrv is a section Curves.
At the endeffekt I want to accomplished a worm like a nest, something like a worm city, where people will live in a worms , to create microclima inside ( In direction of B. Fullers dome), it term that one ring(segment) of each worm is a place for 50 or more habitants. Prox. Pro worm 250-500 habitants.
My steps are:
To make a Srf’s from accomplished wireframe.
Then evaluate this surface with Ecotect (that is why I am still using GH 0.6 because of Uto’s plugin for 0.6 and 0.7). And I also have a Rhino 0.4 Sr6
Make a sun reacting facade or pneumocells.
Make a def. to assign a GH def. on multiply Crv’s. For this I need also evaluate a Crv’s length, because of subdivisions number. If I assign the same divisions number to all Crv’s , the longest and the shortest will be divided at same div. Num.! What we don’t see in a nature.
Make a living space inside of worm, with vertical farming, residents, parks etc.... Dividing a worm Srf’s on separated rings (segments) , to count their area. Bigger ring will have a more people and so on...
Make a model :)
I hope that I don’t sound too much pretentious :)…
n due at the end of march. i am hoping to see if i can do this as a sort of "HIVE MIND" experiment with one or two or more posters to the forum. i have uploaded two files to http://www.formpig.com/nine_bar-FAR and I have the following goals:
1. To "kinematically iterate" various formal building envelopes based upon a 50' x 100' lot that "conform" to the nine bar linkage geometry.
2. This lot would have "setbacks" consisting of two 5' side setbacks, a 10' rear yard setback and a 25' front yard setback. max height on the structure is 32' and the allowable overhangs into the setbacks are 2'. I would like to find a way to use the "nine bar geometry" to construct a series of iterations for "floors", "walls" and "ceilings", which would then be tied to a volumetric (cubic volume), or a total square footage (perhaps based upon two horizontal section cuts) which was based upon a given number that I will provide per local building code.
3. Laid on top of this we would also have "mcmansion ordinance" requirements based upon the pdf enclosed. i expect to have this "tent restriction" data in digital form to upload to ftp shortly.
It would be up to you individually or collectively to determine how best to position this "in the real world" based upon the lot, setbacks, zoning requirements etc. For instance, perhaps the nine bar configuration has its vertices coplanar with the 50' x 100' x 32' envelope restrictions and then the chosen volume is "trimmed' by the setback requirements. Or perhaps the nine-bar configuration is generated completely within the setbacks, or perhaps it is generated 2' outside of the setbacks so as to take advantage of the 2' overhang allowance on the setbacks, etc.
*
Given an opportunity to develop the work in a second phase we would have an opportunity to tie this into various efficiencies such as Bill of Materials (wall floor and ceiling square foot calculations), envelope to volume calculations, solar panel efficiencies (solar orientation and envelope geometry) etc, etc (love to get suggestions for this).
*
I've become /really/ convinced that this would be a /really/ interesting entry based upon my just finishing up Kas Oosterhuis' Towards a New Kind of Building: A Designer's Guide for Non-Standard Architecture". In an ideal world I was hoping that it would be possible to hash this out discussion-wise and then literally passing it around on the list after someone eventually made the first move by tossing out a rough ghx script. My expectation would be to finalize it rapidly in the next two weeks. Something of a contemporary version of a design charette.
However, I realize this may not be workable so if you have experience in this arena and particularly if you think this is a brief that is straighforward enough to be almost literally implemented in Grasshopper, please contact me for any wage and/or contract fee requirements.
I'm getting a bit of a late jump on this but my hope is that with the right participant(s) that I can thrash it together quick enough for the first round.
info@formpig.com…
th (60° max in Paris), but the problem stil arises for the angle theta (for the south but also for the others orientations). For the diffuse radiation, this difference should be 10% as you noticed.
2) I have done some simulations and tried to analyse the weather file used. You can find my results in the Excel File attached. Some simulations take into account the glazing and others just determine the "occultation factor" of the shading device, to which I apply then the solar factor of the window. I found there is a noticeable difference between "_shading_1" and "_Focc_1" for exemple, we should have found similar values ... ? It seems to happen something strange when the rays passe through the glass to reach the analysis points. Facing those results, I still have trouble to draw conclusions. I also determined the diffuse part of radiations for each day from the weather file used, it may help to understand ... If you have any suggestion to explain those results, please let me know.
3) Another point attracts my attention :
The horizontal infrared radiation intensity of the weather file is quite high and constant. I'm wondering if HB take into account this solar radiation's component which represent about 50% of the solar energy ?!
http://bigladdersoftware.com/epx/docs/8-3/auxiliary-programs/energyplus-weather-file-epw-data-dictionary.html#field-horizontal-infrared-radiation-intensity
I continue my research about what is going under the hood (reading documents on Radiance and Daysim calculations) and let you know about the progress of my searches.
Thank you again for your support !
Regards,
Severine
…
[2 of 8] No context surfaces...5. [3 of 8] Writing geometry...6. [4 of 8] Writing Electric Load Center - Generator specifications ...7. [5 of 8] Writing materials and constructions...8. [6 of 8] Writing schedules...9. [7 of 8] Writing loads and ideal air system...10. [8 of 8] Writing outputs...11. ...... idf file is successfully written to : C:\Users\Personal\Desktop\TESI\x006\THOR001\EnergyPlus\THOR001.idf12. 13. Analysis is running!...14. C:\Users\Personal\Desktop\TESI\x006\THOR001\EnergyPlus\eplusout.csv15. ......
Done! Read below for errors and warnings:
16. 17. Program Version,EnergyPlus, Version 8.3.0-6d97d074ea, YMD=2016.01.17 17:56,IDD_Version 8.3.018. 19. ** Warning ** IP: Note -- Some missing fields have been filled with defaults. See the audit output file for details.20. 21. ************* Beginning Zone Sizing Calculations22. 23. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)24. 25. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00126. 27. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00128. 29. ** ~~~ ** (Dot Product indicator=184.4593)30. 31. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.32. 33. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)34. 35. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00136. 37. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00138. 39. ** ~~~ ** (Dot Product indicator=184.4593)40. 41. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.42. 43. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)44. 45. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00146. 47. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00148. 49. ** ~~~ ** (Dot Product indicator=184.4593)50. 51. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.52. 53. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)54. 55. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00156. 57. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD1 is in front of receiving surface=PELLE_COMUNIONE00158. 59. ** ~~~ ** (Dot Product indicator=184.4593)60. 61. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.62. 63. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)64. 65. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00166. 67. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00168. 69. ** ~~~ ** (Dot Product indicator=184.4593)70. 71. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.72. 73. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)74. 75. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00176. 77. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00178. 79. ** ~~~ ** (Dot Product indicator=184.4593)80. 81. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.82. 83. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)84. 85. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00186. 87. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00188. 89. ** ~~~ ** (Dot Product indicator=184.4593)90. 91. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.92. 93. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)94. 95. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=00196. 97. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE00198. 99. ** ~~~ ** (Dot Product indicator=184.4593)100. 101. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.102. 103. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)104. 105. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001106. 107. ** ~~~ ** because vertex 1 of back surface=PELLE_COMUNIONE002 is in front of receiving surface=PELLE_COMUNIONE001108. 109. ** ~~~ ** (Dot Product indicator=184.4593)110. 111. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.112. 113. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)114. 115. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001116. 117. ** ~~~ ** because vertex 2 of back surface=PELLE_COMUNIONE002 is in front of receiving surface=PELLE_COMUNIONE001118. 119. ** ~~~ ** (Dot Product indicator=184.4593)120. 121. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.122. 123. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)124. 125. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001126. 127. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001128. 129. ** ~~~ ** (Dot Product indicator=182.6148)130. 131. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.132. 133. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)134. 135. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001136. 137. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001138. 139. ** ~~~ ** (Dot Product indicator=92.2297)140. 141. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.142. 143. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)144. 145. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001146. 147. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001148. 149. ** ~~~ ** (Dot Product indicator=92.2297)150. 151. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.152. 153. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)154. 155. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001156. 157. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001158. 159. ** ~~~ ** (Dot Product indicator=182.6148)160. 161. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.162. 163. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)164. 165. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001166. 167. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001168. 169. ** ~~~ ** (Dot Product indicator=92.2297)170. 171. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.172. 173. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)174. 175. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001176. 177. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001178. 179. ** ~~~ ** (Dot Product indicator=182.6148)180. 181. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.182. 183. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)184. 185. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001186. 187. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001188. 189. ** ~~~ ** (Dot Product indicator=92.2297)190. 191. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.192. 193. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)194. 195. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001196. 197. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001198. 199. ** ~~~ ** (Dot Product indicator=1.8446)200. 201. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.202. 203. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)204. 205. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001206. 207. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001208. 209. ** ~~~ ** (Dot Product indicator=1.8446)210. 211. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.212. 213. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)214. 215. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001216. 217. ** ~~~ ** because vertex 1 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001218. 219. ** ~~~ ** (Dot Product indicator=92.2297)220. 221. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.222. 223. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)224. 225. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001226. 227. ** ~~~ ** because vertex 2 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001228. 229. ** ~~~ ** (Dot Product indicator=1.8446)230. 231. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.232. 233. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)234. 235. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001236. 237. ** ~~~ ** because vertex 3 of back surface=WIN_006_GLZP_3 is in front of receiving surface=PELLE_COMUNIONE001238. 239. ** ~~~ ** (Dot Product indicator=92.2297)240. 241. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.242. 243. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)244. 245. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001246. 247. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE001248. 249. ** ~~~ ** (Dot Product indicator=184.4593)250. 251. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.252. 253. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)254. 255. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001256. 257. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE001258. 259. ** ~~~ ** (Dot Product indicator=184.4593)260. 261. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.262. 263. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)264. 265. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001266. 267. ** ~~~ ** because vertex 1 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE001268. 269. ** ~~~ ** (Dot Product indicator=184.4593)270. 271. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.272. 273. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)274. 275. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001276. 277. ** ~~~ ** because vertex 2 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE001278. 279. ** ~~~ ** (Dot Product indicator=184.4593)280. 281. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.282. 283. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)284. 285. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001286. 287. ** ~~~ ** because vertex 1 of back surface=WIN_001_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001288. 289. ** ~~~ ** (Dot Product indicator=180.7210)290. 291. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.292. 293. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)294. 295. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001296. 297. ** ~~~ ** because vertex 3 of back surface=WIN_001_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001298. 299. ** ~~~ ** (Dot Product indicator=180.7210)300. 301. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.302. 303. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)304. 305. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001306. 307. ** ~~~ ** because vertex 2 of back surface=WIN_001_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001308. 309. ** ~~~ ** (Dot Product indicator=180.7210)310. 311. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.312. 313. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)314. 315. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001316. 317. ** ~~~ ** because vertex 3 of back surface=WIN_001_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001318. 319. ** ~~~ ** (Dot Product indicator=180.7210)320. 321. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.322. 323. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)324. 325. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001326. 327. ** ~~~ ** because vertex 3 of back surface=PELLE_OVEST is in front of receiving surface=PELLE_COMUNIONE001328. 329. ** ~~~ ** (Dot Product indicator=184.4593)330. 331. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.332. 333. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)334. 335. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001336. 337. ** ~~~ ** because vertex 4 of back surface=PELLE_OVEST is in front of receiving surface=PELLE_COMUNIONE001338. 339. ** ~~~ ** (Dot Product indicator=184.4593)340. 341. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.342. 343. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)344. 345. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001346. 347. ** ~~~ ** because vertex 1 of back surface=WIN_002_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001348. 349. ** ~~~ ** (Dot Product indicator=180.7210)350. 351. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.352. 353. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)354. 355. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001356. 357. ** ~~~ ** because vertex 3 of back surface=WIN_002_GLZP_0 is in front of receiving surface=PELLE_COMUNIONE001358. 359. ** ~~~ ** (Dot Product indicator=180.7210)360. 361. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.362. 363. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)364. 365. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001366. 367. ** ~~~ ** because vertex 2 of back surface=WIN_002_GLZP_1 is in front of receiving surface=PELLE_COMUNIONE001368. 369. ** ~~~ ** (Dot Product indicator=180.7210)370. 371. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.372. 373. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)374. 375. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001376. 377. ** ~~~ ** because vertex 1 of back surface=WIN_002_GLZP_2 is in front of receiving surface=PELLE_COMUNIONE001378. 379. ** ~~~ ** (Dot Product indicator=180.7210)380. 381. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.382. 383. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)384. 385. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001386. 387. ** ~~~ ** because vertex 3 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001388. 389. ** ~~~ ** (Dot Product indicator=184.4593)390. 391. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.392. 393. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)394. 395. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001396. 397. ** ~~~ ** because vertex 4 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001398. 399. ** ~~~ ** (Dot Product indicator=184.4593)400. 401. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.402. 403. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)404. 405. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001406. 407. ** ~~~ ** because vertex 7 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001408. 409. ** ~~~ ** (Dot Product indicator=184.4593)410. 411. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.412. 413. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)414. 415. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001416. 417. ** ~~~ ** because vertex 8 of back surface=PELLE_SOTTO is in front of receiving surface=PELLE_COMUNIONE001418. 419. ** ~~~ ** (Dot Product indicator=184.4593)420. 421. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.422. 423. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)424. 425. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001426. 427. ** ~~~ ** because vertex 1 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001428. 429. ** ~~~ ** (Dot Product indicator=184.4593)430. 431. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.432. 433. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)434. 435. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001436. 437. ** ~~~ ** because vertex 4 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001438. 439. ** ~~~ ** (Dot Product indicator=184.4593)440. 441. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.442. 443. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)444. 445. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001446. 447. ** ~~~ ** because vertex 5 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001448. 449. ** ~~~ ** (Dot Product indicator=184.4593)450. 451. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.452. 453. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)454. 455. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001456. 457. ** ~~~ ** because vertex 8 of back surface=PELLE_SOPRA_DUP is in front of receiving surface=PELLE_COMUNIONE001458. 459. ** ~~~ ** (Dot Product indicator=184.4593)460. 461. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.462. 463. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)464. 465. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001466. 467. ** ~~~ ** because vertex 1 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002468. 469. ** ~~~ ** (Dot Product indicator=167.5695)470. 471. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.472. 473. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)474. 475. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001476. 477. ** ~~~ ** because vertex 2 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002478. 479. ** ~~~ ** (Dot Product indicator=167.5695)480. 481. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.482. 483. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)484. 485. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001486. 487. ** ~~~ ** because vertex 3 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002488. 489. ** ~~~ ** (Dot Product indicator=195.1092)490. 491. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.492. 493. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)494. 495. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001496. 497. ** ~~~ ** because vertex 4 of back surface=PELLE_NORD2 is in front of receiving surface=PELLE_COMUNIONE002498. 499. ** ~~~ ** (Dot Product indicator=195.1092)500. 501. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.502. 503. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)504. 505. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001506. 507. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE001 is in front of receiving surface=PELLE_COMUNIONE002508. 509. ** ~~~ ** (Dot Product indicator=167.5695)510. 511. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.512. 513. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)514. 515. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001516. 517. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE001 is in front of receiving surface=PELLE_COMUNIONE002518. 519. ** ~~~ ** (Dot Product indicator=167.5695)520. 521. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.522. 523. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)524. 525. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001526. 527. ** ~~~ ** because vertex 1 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002528. 529. ** ~~~ ** (Dot Product indicator=32.0568)530. 531. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.532. 533. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)534. 535. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001536. 537. ** ~~~ ** because vertex 2 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002538. 539. ** ~~~ ** (Dot Product indicator=139.1556)540. 541. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.542. 543. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)544. 545. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001546. 547. ** ~~~ ** because vertex 3 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002548. 549. ** ~~~ ** (Dot Product indicator=139.1556)550. 551. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.552. 553. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)554. 555. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001556. 557. ** ~~~ ** because vertex 4 of back surface=WIN_005 is in front of receiving surface=PELLE_COMUNIONE002558. 559. ** ~~~ ** (Dot Product indicator=32.0568)560. 561. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.562. 563. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)564. 565. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001566. 567. ** ~~~ ** because vertex 1 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002568. 569. ** ~~~ ** (Dot Product indicator=167.5695)570. 571. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.572. 573. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)574. 575. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001576. 577. ** ~~~ ** because vertex 2 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002578. 579. ** ~~~ ** (Dot Product indicator=167.5695)580. 581. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.582. 583. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)584. 585. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001586. 587. ** ~~~ ** because vertex 3 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002588. 589. ** ~~~ ** (Dot Product indicator=167.5695)590. 591. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.592. 593. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)594. 595. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001596. 597. ** ~~~ ** because vertex 4 of back surface=PELLE_COMUNIONE003 is in front of receiving surface=PELLE_COMUNIONE002598. 599. ** ~~~ ** (Dot Product indicator=167.5695)600. 601. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.602. 603. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)604. 605. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001606. 607. ** ~~~ ** because vertex 1 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002608. 609. ** ~~~ ** (Dot Product indicator=195.1092)610. 611. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.612. 613. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)614. 615. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001616. 617. ** ~~~ ** because vertex 2 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002618. 619. ** ~~~ ** (Dot Product indicator=195.1092)620. 621. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.622. 623. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)624. 625. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001626. 627. ** ~~~ ** because vertex 3 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002628. 629. ** ~~~ ** (Dot Product indicator=195.1092)630. 631. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.632. 633. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)634. 635. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001636. 637. ** ~~~ ** because vertex 4 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002638. 639. ** ~~~ ** (Dot Product indicator=195.1092)640. 641. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.642. 643. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)644. 645. ** ~~~ ** Solar Distribution = FullInteriorExterior will not work in Zone=001646. 647. ** ~~~ ** because vertex 5 of back surface=PELLE_EST is in front of receiving surface=PELLE_COMUNIONE002648. 649. ** ~~~ ** (Dot Product indicator=195.1092)650. 651. ** ~~~ ** Check surface geometry; if OK, use Solar Distribution = FullExterior instead.652. 653. ** Severe ** Problem in interior solar distribution calculation (CHKBKS)654. [...]
thisthe errorthat appen when i lunch E+ with only one zone....what is going on???? …
strain for the moment.
Other than that:
1. On this type of structures equal members (although achievable) is not a consideration unless you use some type of MERO system and you have a zillion members in mind (balls must being drilled on a per ball basis, mind). But you are not after a MERO. Or ... you have "fixed" panels in mind that "fit" in your facets and make the envelope?? (but this is more theoretical than anything ... ).
2. Individually picking items in collections (your nodes for instance) although the essence of engineering ... is not achievable in GH unless you use code (I could easily provide a small demo on that matter using C# - it could change your perception on things rather drastically).
3: Academic means ... er ... academic, he he: something NOT related with a real-life project meaning that the level of detail and the whole approach is ... er ... hmm ... "indicative". Academic also means: non-profitable (in the strict sense).
Suggestions:
A. This type of stuff is 50% about designing a proper node. Provide some detailed sketches on that matter (BTW: "mobile" nodes ???). The more "accurate" they are the better. Using wood makes the structure "heavy" to the eye (and is BAD: killing trees for doing things?? No good at all - unless is fully synthetic [kitsch], that is).
B. The remaining 49.99% is the envelope: Provide ... blah, blah. Note: if the envelope "panels" are NOT engulfed in the facets (say: some planar glazing system and the likes) then the nodes MUST provide means to support the envelope as well (or at least the Primary support system). By Primary I mean "big" triangular frames that support a "grid" of smaller ones that host glass, poly carbonate sheets or some other stuff.
C: For a vast variety of reasons going from "abstract" to something "realistic" on that type of structures requires coding. Are you familiar with such freaky things? (C# for instance) OR do you have issues using a "component" that is made that way? (see 2).
…
visiting school will continue its engagement with Mexico City from an infrastructural point of view taking advantage of the challenges and opportunities it poses/offers for the viability of one of the biggest metropolis on earth. The workshop will be constructed around key infrastructural issues such as the “Recovering of Waterscapes” and the “Reinforcement of Mobility Networks”. They will form the spine for the intervention through PROTOTYPICAL strategies within a tactical URBANISM framework.
The objective will be to explore and develop the concept of “urban prototype” capable of accommodating change and a degree of indeterminacy within the design process which will acquire its specificity by means of its on-site materialization. Paradigms of self-organized systems, distributed networks and uprising complexity will be introduced through systemic based design techniques, setting up counter models to conventional urban design and planning.
Based on this brief, students will have the opportunity to develop their skills through different methodologies based on the exploration of local conditions, engineering techniques, material processes, and the experimentation with digital, fabrication and representational tools.
The visiting school will run parallel units by AA tutors and graduates from across the school giving participants the opportunity to experiment the different lines of research currently being developed at the AA, in particular the visiting school will directly engage with the investigations within the research cluster “Urban Prototypes “.
In addition to this a symposium and series of lecture will to bring key figures, local and international, directly related to the design of the city (Minister of Urban development, architects and urban designers, authorities, artists among others). The event will finish with students presenting their work to local authorities and relevant actors and a public exhibition of the results.
Eligibility
The workshop is open to current architecture and design students, phd candidates and young professionals. All applicants should submit a CV and portfolio.
Applications
The deadline for applications is 11 June 2012. Application forms and additional information are available online at: www.prototypicalnetworks.net and applications can be submitted to: visitingschool@aaschool.ac.uk.
Schedule & Venue
The school runs in summer from 25/06/2012 to 06/07/2012 in Mexico City. This is an intensive, studio-based programme requiring full-time participation.
Accommodation & Costs
Accommodation during the workshop is not provided, but accommodation at an affordable hotel can be advised. The AA Visiting School requires a fee of £695 per participant which includes a £50 Visiting Student Membership, made payable to the AA School of Architecture.…
Horticulture and Landscape in same time.
The most common plastic materials used as agricultural films are the low density polyethylene (LDPE, with a density less than 0.93 kg m−3), the copolymer of ethylene and vinyl-acetate (EVA)
Also here you can find the characteristics of the flexible materials for greenhouse covers (adapted from CPA, 1992 and Tesi, 2001) as much as i get.
UV-PE Film ( UV-PE~ polyethylene Long life or UV)
Thickness (mm) = 0.18
Direct PAR transmissivity (%) = 90
Diffuse PAR transmissivity (%)= 86
Long-wave IR transmissivity (%)= 65
EVA Film ( EVA~Ethylene vinyl-acetate copolymer)
Thickness (mm) = 0.18
Direct PAR transmissivity (%) = 90
Diffuse PAR transmissivity (%)= 76
Long-wave IR transmissivity (%)= 27
and here you will find the global heat transfer coefficient’ (K in W m−2 °C−1) for the above greenhouse covering materials, measured under normalized conditions (temperatures: exterior: −10°C, interior: +20°C, wind: 4 m s−1). (Source: Nisen and Deltour, 1986.)
Cover Clear sky Overcast Sky
Single PE 8.8-9.0 7.1- 7.2
Single EVA 7.8 6.6
Note : the PAR radiation (photosynthetically active or photoactive radiation and its the amounts to 45–50% of the global radiation; Berninger, 1989)
The name PAR is used to designate the radiation with wavelengths useful for plant photosynthesis. It is accepted that the PAR radiation ranges from 400 to 700 nm (McCree, 1972), although some authors consider the PAR from 350 to 850 nm.
The composition of the radiation changes with time, as a function of the Sun’s elevation and the cloudiness. When the Sun is low over the horizon, the short wavelengths are reduced (less UV and more red). The clouds reduce the amount of energy, greatly decreasing the NIR.
The PAR proportion in relation to the global radiation increases with scattering (diffusion). It is lower with clear sky and in the summer (45–48%).
kind regards
rafat …
lite’ of education that promotes the Architectural Association’s exclusive, intensive form of teaching and learning around the country. AA Greece VS aims on visiting a different city each year and construct a single large-scale model which will act as an active nod of communication among the various locations.
In 2014, the School will initiate its design agenda with an architectural approach that is focused on the aspect of connection. The city of Patras which is the starting node of AA Greece VS, was chosen by the European Commission to be the European Capital of Culture for the year 2006. The concept of the event revolved around the main theme of "Bridges" and "Dialogues", drawing benefit from the city's rich history and its position as a "Gate to the West", to underline the essence of the productive interaction of culture and civilizations in Europe. The AA Greece Visiting School investigates how well existing buildings with various sightlines and variant spatial grammars perform according to human perception. In sync with the flexible and adaptive concept of parasitical structures, the research focuses on the making of transformable large-scale creations that accentuate prominent architectural features of existing buildings. The research looks at how cultural factors, specific preferences, experiences, and expectations can lead to the transformation of architectural parasitical structures.
Discounts
1. Standard application
The AA Visiting School requires a fee of £600 per participant, which includes a £60 Visiting Membership. If you are already a member, the total fee will be reduced automatically by £60 by the online payment system. Fees are non-refundable.
2. Group registration
For group applications, there will be a range of discounts depending on the number of people in the group. The discounted fee will be applied to each individual in the group.
1. 3-6 people group: £60 (AA Membership fee) + 540*0.75 = £465 (25 %)
2. 7-15 people group: £60 + 540*0.70 = £438 (30%)
3. more than 15 people group: £60 + 540*0.65 = £411 (35%)
3. AA students
For current AA students studying in Undergraduate or Graduate programs, a discount of 50% will be made for each participant. (AA students are exempt of paying the £60 membership fee.)
Eligibility The workshop is open to architecture and design students and professionals worldwide. Participants receive the Architectural Association certificate of participation upon completion.
Applications
The deadline for applications is 15 September 2014. Online application form and payment required. No portfolio/CV required. The online application can be reached from the link below:
https://www.aaschool.ac.uk/STUDY/ONLINEAPPLICATION/visitingApplication.php?schoolID=273
Contact:
Alexandros.Kallegias@aaschool.ac.uk…
ll-Facade using Rhino and Grasshopper Participants will learn; Rhinoceros Grasshopper Advanced Parametric Design Brick Formations and Explorations Shadow-Design Relationship
Session 2: Advanced Digital Modeling for Additive Manufacturing (3D Printing) Participants will learn; How to prepare a 3D design to 3D Printing process in Rhinoceros Advanced Methods for 3D Print optimisation for time and cost effective production 3D Printing software education Cura
INFO
Date Saturday, 28 September 2019 Schedule 9:30am – 2:30pm (Session 1) | 2:45pm – 7:00pm (Session2) Venue (TBC) Pada Labs, Istanbul Language English/Turkish Softwares Rhinoceros Grasshopper 3D Cura Participants will need to bring their own laptops with software installed; other plugins will be distributed at the workshop. Prerequisites All tutorials are open to beginner level. No previous knowledge of Cura and Grasshopper needed. Basic knowledge of Rhinoceros recommended. Participation The workshop is limited to the first 20 applicants. Each student will receive a certificate of participation. Prices for each session: (You can pick one and attend one) Special Early registration (Deadline 1 August ) Students 310 TL Professionals 400 TL Regular registration Students 390 TL Professionals 480 TL Prices for Session 1&2 Combined: (Full Day) Special Early registration (Deadline 1 August ) Students 540 TL Professionals 690 TL Regular registration Students 620 TL Professionals 790 TL DISCOUNTS Group registration of 3 or more people will get a 15% discount. * Previous Pada workshop students will get a 10% discount. DIRECTOR Begum Aydinoglu, M.Arch AA DRL will be instructing and directing the following workshops. REGISTRATION: Email to pada.workshops@gmail.com for registration instructions. Please note that we have limited seats and there won't be any exceptions. …