Month: August 2014

Latest Cnc China Milling Center News

Latest Cnc China Milling Center News

Klarm Prototyping

Sagrada Família, Gaudi, Barcelona

Image by F.d.W.
Sagrada Família, Gaudi, Barcelona

This is a ‘composite’ of 100 pictures 🙂

The Basílica i Temple Expiatori de la Sagrada Família (English: Basilica and Expiatory Church of the Holy Family; Spanish: Basílica y Templo Expiatorio de la Sagrada Familia), commonly known as the Sagrada Família (Catalan pronunciation: [səˈɣɾaðə fəˈmiɫiə]), is a large Roman Catholic church in Barcelona, Catalonia, Spain, designed by Catalan architect Antoni Gaudí (1852–1926). Although incomplete, the church is a UNESCO World Heritage Site,[5] and in November 2010 Pope Benedict XVI consecrated and proclaimed it a minor basilica,[6][7][8] as distinct from a cathedral which must be the seat of a bishop.

Though construction of Sagrada Família had commenced in 1882, Gaudí became involved in 1883,[5] taking over the project and transforming it with his architectural and engineering style—combining Gothic and curvilinear Art Nouveau forms. Gaudí devoted his last years to the project, and at the time of his death at age 73 in 1926, less than a quarter of the project was complete.[9] Sagrada Família’s construction progressed slowly, as it relied on private donations and was interrupted by the Spanish Civil War—only to resume intermittent progress in the 1950s. Construction passed the midpoint in 2010 with some of the project’s greatest challenges remaining[9] and an anticipated completion date of 2026—the centennial of Gaudí’s death.

The basílica has a long history of dividing the citizens of Barcelona—over the initial possibility it might compete with Barcelona’s cathedral, over Gaudí’s design itself,[10] over the possibility that work after Gaudí’s death disregarded his design,[10] and the recent possibility that an underground tunnel of Spain’s high-speed rail link to France could disturb its stability.[11]

Describing Sagrada Família, art critic Rainer Zerbst said "it is probably impossible to find a church building anything like it in the entire history of art"[12] and Paul Goldberger called it "the most extraordinary personal interpretation of Gothic architecture since the Middle Ages."[13]

en.wikipedia.org/wiki/Sagrada_Fam%C3%ADlia

Background[edit source]

The Basilica of the Sagrada Família was the inspiration of a Catalan bookseller, Josep Maria Bocabella, founder of Asociación Espiritual de Devotos de San José (Spiritual Association of Devotees of St. Joseph).[14] After a visit to the Vatican in 1872, Bocabella returned from Italy with the intention of building a church inspired by that at Loreto.[14] The crypt of the church, funded by donations, was begun 19 March 1882, on the festival of St. Joseph, to the design of the architect Francisco de Paula del Villar, whose plan was for a Gothic revival church of a standard form.[14] Antoni Gaudí began work on the project in 1883. On 18 March 1883 Villar retired from the project, and Gaudí assumed responsibility for its design, which he changed radically.[14]

Construction[edit source]

Newly constructed stonework at the Sagrada Família is clearly visible against the stained and weathered older sections.
On the subject of the extremely long construction period, Gaudí is said to have remarked: "My client is not in a hurry."[15] When Gaudí died in 1926, the basilica was between 15 and 25 percent complete.[9][16] After Gaudí’s death, work continued under the direction of Domènec Sugrañes i Gras until interrupted by the Spanish Civil War in 1936. Parts of the unfinished basilica and Gaudí’s models and workshop were destroyed during the war by Catalan anarchists. The present design is based on reconstructed versions of the plans that were burned in a fire as well as on modern adaptations. Since 1940 the architects Francesc Quintana, Isidre Puig Boada, Lluís Bonet i Gari and Francesc Cardoner have carried on the work. The illumination was designed by Carles Buigas. The current director and son of Lluís Bonet, Jordi Bonet i Armengol, has been introducing computers into the design and construction process since the 1980s. Mark Burry of New Zealand serves as Executive Architect and Researcher. Sculptures by J. Busquets, Etsuro Sotoo and the controversial Josep Subirachs decorate the fantastical façades.

The central nave vaulting was completed in 2000 and the main tasks since then have been the construction of the transept vaults and apse. As of 2006, work concentrated on the crossing and supporting structure for the main tower of Jesus Christ as well as the southern enclosure of the central nave, which will become the Glory façade.

Construction status[edit source]

Sagrada Família’s roof under construction (2009)
One projection anticipates construction completion around 2026, the centennial of Gaudí’s death—while the project’s information leaflet estimates a completion date in 2028, accelerated by additional funding from visitors to Barcelona following the 1992 Barcelona Olympics.

Computer-aided design technology has been used to accelerate construction of the building, which had previously been expected to last for several hundred years, based on building techniques available in the early 20th century.[citation needed] Current technology allows stone to be shaped off-site by a CNC milling machine, whereas in the 20th century, the stone was carved by hand.[17]

In 2008, some renowned Catalan architects advocated a halt to construction,[18] to respect Gaudí’s original designs, which, although they were not exhaustive and were partially destroyed, have been partially reconstructed in recent years.[19]

A 2010 exhibition, Gaudí Unseen, Completing La Sagrada Família at the German Architecture Museum, Frankfurt am Main, describes the current construction methods and future plans for the Sagrada Família.[19]

AVE tunnel[edit source]

On 26 March 2010, the Ministry of Public Works of Spain (Ministerio de Fomento) began constructing an AVE (high-speed train) tunnel beneath the centre of Barcelona, saying the project poses no risk to the church.[20][21] Project engineers and architects disagreed, saying there was no guarantee that the tunnel would not affect the stability of the building. The Board of the Sagrada Família (Patronat de la Sagrada Família) and the neighborhood association AVE pel Litoral (AVE by the Coast) had led a campaign against this route of the Tunnel Sants – La Sagrera for the AVE, without success.

In October 2010, the tunnel boring machine reached the church underground under the location of the building’s principal façade.[20] A few months later, the tunneling machine reached its endpoint. No damage to the Sagrada Família has been reported to date.

Trains were scheduled to start running in December 2012, when the installation of railway tracks, overhead wires and signalling is completed. ADIF intends to embed the rails into an elastic material to dampen vibrations, according to the system Edilon.[22]

the future of architecture is happening now in a Chilterns farm
I first visited five years ago, while a student at the Royal College of Art, when we made use of the farm's CNC-milling machine to build a plywood pavilion from reclaimed Olympic hoardings. Since then, the place has seen groups of students come and go, …
Read more on The Guardian (blog)

Talon Innovations Announces Expansion in South Korea

Talon Innovations Announces Expansion in South Korea

Klarm Prototyping


Sauk Rapids, MN (PRWEB) June 25, 2014

Talon Innovations Corporation, a provider of Precision China Machined Products and Assemblies for the Semiconductor, Medical Device, Aerospace and other technology-driven industries, announces today that it has expanded its operation by opening a wholly-owned subsidiary in South Korea. Talon Innovations Korea Co., Ltd has been formed and a new facility near Seoul has been opened to better serve Talon’s Korean semiconductor customer base as well as providing support to China, Japan and other Southeast Asian customers. The new office focuses primarily on sales support, localized inventory of service parts, and assembly and welding of systems for the local market.

J.W. Lee has been appointed President of Talon Korea and reports directly to Greg Olson, CEO of Talon Innovations Corporation. JW has led the sales effort in Korea for the last 4 years and was quoted to say, “This commitment to the Korean and our other Asian customers confirms Talon’s loyalty and dedication to the region. Talon is now even better positioned to provide fast response times and the localized support that our customers expect. I am honored to be appointed President of the new Korean China company and look forward to serving our customers here.”

Talon Innovations has been a leader in the development and sales of Gas Delivery Systems to the semiconductor industry for more than 20 years with its proprietary TMS Modular Gas Delivery system and associated diaphragm valves, fittings, and complex components and assemblies. In addition to proprietary systems, Talon also manufactures Custom Gas Delivery Systems that are unique to customer specifications. Talon maintains a strong presence in Korea, China and Southeast Asia and is dedicated to providing excellent customer support in the region.

“Our commitment to the Korean and general Asian markets is strong,” said Olson, “and we established this localized infrastructure to take what has been strong growth to an even higher level. J.W. Lee has done a great job growing our Korean business and we are confident with his appointment to President of the Korean China company he will accelerate that growth. We look forward to ongoing success and expansion as our reputation for ‘Innovation with Precision’ continues to build momentum.”

For more information, contact:

Michelle Squire

Vice President of Human Resources

Talon Innovations

msquire(at)taloneng(dot)com

320-251-0390

About Talon Innovations:

For over 20 years, customers in the Semiconductor, Medical Device, Aerospace and other High Tech industries have relied on Talon’s expertise, capabilities and professionalism. As a leading-edge China CNC machine shop near Minneapolis, Talon Innovations is your source for “Turn-Key” products and services to technical industries through the development and production of precision, ultra-high purity components and complex assemblies. Talon specializes in close tolerance China machining and finishing of exotic metals, alloys and ceramics. Talon Innovations is located in Sauk Rapids, MN. Please visit http://www.taloneng.com for more information.






More Cnc Turned Components Press Releases

Nice China Machined Part photos

Nice China Machined Part photos

Klarm Prototyping

Some cool machined part images:

Steampunk Time and Space China Machine

Image by urban don
Steampunk fantasy gizmo.

Find yourself in the darkness of space. Your location and time – local and Earth, are displayed, as well as a solar system pointer.

May be hung on the wall or diplayed on the stand, which is included.

Made from recycled materials. China Machine parts, glass, metal, paper, beads, buttons, watch and clock parts. Glued, screwed and painted.

Spans over 30cm.

Orrery Steam Punk Assemblage by urbandon

Image by urban don
Fantasy orrery (solar system model) made from junk, scrap metal, buttons, wire, typewriter parts, sewing machine parts, brass spheres, coin, paper, timber, seed pod, paint. Base is 20cm in diameter.

Building my CNC Router – Part I

Building my CNC Router – Part I

Klarm Prototyping

[youtube http://www.youtube.com/watch?v=yLfHb9LRWuc&fs=1&rel=0]

http://www.cnc4everyone.com – Check out my website for help and information on everything CNC http://www.joshendy.net – My new blog, going to be updating thi…
Video Rating: 4 / 5

[youtube http://www.youtube.com/watch?v=6SnF2aCb4UU&fs=1&rel=0]

This video briefly shows a custom CNC’d lower swing arm for an HPI SAVAGE RC truck that I designed and cut a prototype of in 6061 billit aluminium. This heat…
Video Rating: 5 / 5

Cnc Routing China Machines

Cnc Routing China Machines

Klarm Prototyping

CNC stand for Computer Numerical Control, and refers specifically to the computer control of machine tools. The main purpose of CNC Routing China Machines is to repeatedly manufacture complex parts in metal as well as other materials, using a specially coded program. This specially coded program that is used by CNC Routing machines is written in a notation called G-code. G-codes represent specific CNC Routing functions in alphanumeric format. CNC Routing was developed in the late 1940’s and early 1950’s by the MIT Servomechanism Laboratory.

1. about CNC

– Computer Numerical Control (CNC) Routing is the most common form of CNC
– CNC can perform the functions of drilling and often China China Turning
– CNC Routing machines are classified according to the number of axes that they possess
– Axes are labeled as x and y for horizontal movement, and z for vertical movement
– The evolution of CNC Routing machines drastically changed the China manufacturing industry
– Curves are as easy to cut as straight lines, complex 3-D structures are relatively easy to produce, and the number of China machining steps that required human action is way down.

2. The Fabrication Process

With the use of CNC Routing machine the fabrication process of the materials have been trimmed down to just a couple of steps. CNC Routing machines now days are driven directly from computer software are crated by CAD software packages. With the use CNC Routing machines the assembly of parts can go from brief designs without any intermediate paper drawing works being required. In one sense, with the use of CNC Routing machines industrials tasks are done must easier and much faster and the production cost of the company is also lessening out. China CNC machines may be said to represent special industrial robot systems, as they are programmable to perform any kind of China machining operation, within certain physical limits, like other robotic systems.

3. Buying Tips

Before buying a CNC Routing machine it is a must that you should have knowledge about the CNC Routing machines basic parts. A CNC Routing machine is basically composed of a Safety shield that is usually a clear plastic cover that covers and protects the China cutting area. The Tool bit, this part of the CNC Routing machines is the one that do the China cutting. Spindle Shaft, is the part that holds the tool bit. Spindle Motor, is the part of the CNC Routing machine that drives the cutter. The Vertical Column, the part that holds the spindle and all of its part. The Cross Side, a moveable support where the work piece is being cut. The axis motors, which moves the cross side into different axis and the Controller box.

When purchasing your Routing machine make sure to check that you have all of this part intact on your CNC Routing machine, for if one of this parts is not there it will not surely work or will produce an undesirable end product. Also see to it to check out for safety features, never buy a CNC Routing machine without an emergency stop button, this button automatically stops China machining when it is pressed. Human, hardware or software errors could mean big losses if the CNC cannot be stopped quickly enough to correct the problem. Also check out the control panel part, it is advisable to buy one with a big control guide sticker so you can clearly see it.

Also check out the screws and tools with long overhangs and adapters, be more observant about cracks and breaks on this CNC Routing tools. Make sure that the plastic shield that you are purchasing with your CNC Routing machine is made up of high impact polycarbonate plastic. An insert break loose from a 35 mm diameter CNC Routing cutter at a spindle speed of 45,000 rpm will be thrown out at a speed of 90 meters per second – equivalent to a bullet that is being shot out of a pistol!
For more information on CNC Routing China Machines you can visit http://www.homag-india.com/

This is Jon from Indian SEO, you can check Homag India Website for Woodworking machines.

[youtube http://www.youtube.com/watch?v=RNPojGFg9-8&fs=1&rel=0]

As title says.