The "Fortuna" combined cycle gas turbine (CCGT) power plant at the Lausward location in the port of Düsseldorf was successfully handed over to the customer and operator, the Stadtwerke Düsseldorf public utility company, on January 22, 2016. The power plant has broken three world records: in the acceptance test a maximum electrical net output of 603.8 megawatts (MW) was achieved and the net energy conversion efficiency was around 61.5 percent. In addition, "Fortuna" can also deliver up to around 300 MW for the district heating system of the city of Düsseldorf – a further international peak value for a power plant equipped with only one gas and steam turbine. This increases the overall efficiency of natural gas as a fuel to 85 percent. The heart of the "Fortuna" CCGT power plant is the extremely powerful SGT5-8000H gas turbine from Siemens. Highly efficient and flexible CCGT power plants ideally complement renewable energy sources such as the wind and the sun, which are subject to fluctuations in their power outputs.
China's megacities alone are home to more than 260 million people. These gigantic conurbations have recently undergone rapid growth of almost two percent per year, and are suffering increasing traffic problems caused by the soaring rate of car use. Hence the correspondingly strong demand for solutions for the further development of urban rail transport. The Nanjing customer has now commissioned Siemens to equip metro Ninghe Line with the CBTC automatic train protection system Trainguard MT. The contract includes the CBTC trackside equipment for the 36 kilometer line as well as the ATC equipment of the 24 trains. In the long term more than ten metro lines will be built in Nanjing – of which five alone will or already been feature Siemens signaling technology.Siemens can look back on a long partnership in China with the Nanjing Metro Corporation. Siemens equipped metro line 1, which started running in 2005 and is now 47 kilometers long, as well as metro line 2 in 2010. Line 2 serves 26 stations and forms the east-west tangent of the city of Nanjing in eastern China. Following the extension of the city's metro with line 2, the rail network now covers 85 kilometers. Line 10, Nangjing's first cross-Yangtze river metro line was put into operation on July 1, 2014. Its first phase runs 23.6 kilometers with 14 stations. The latest Nanjing metro line fitted with signaling technology from Siemens is Nanjing Metro Line 3, which went on public operation on April 1, 2015.
Effective October 1, 2016, Siemens will set up a separate unit to foster disruptive ideas more vigorously and to accelerate the development of new technologies. The unit's name, "next47," plays on the fact that Siemens was founded in 1847. At next47, the company will pool its existing startup activities. The new unit will have funding of €1 billion for the first five years. Siegfried Russwurm, Siemens Chief Technology Officer, will head the new unit on an acting basis. The new unit will be given the necessary independence but can nevertheless leverage the advantages offered by Siemens. It will have offices in Berkeley, Shanghai and Munich and cover all regions of the world from those locations. next47 will build on Siemens' existing startup activities. The new unit will be open to employees as well as to founders, external startups and established companies if they want to pursue business ideas in the company's strategic innovation fields.
The Dresser-Rand business, part of Siemens Power and Gas, has commissioned its first micro-scale natural gas liquefaction system at the Ten Man liquefied natural gas (LNG) facility in Pennsylvania, U.S. The modular, portable LNGo technology enables distributed production of LNG and can be installed in a short period of time to meet local demand for LNG. This cost-effective solution, developed by the Dresser-Rand business, allows the operator, Frontier Natural Resources, to monetize stranded gas assets at Tenaska Resources LLC's Mainesburg field, located in the Marcellus shale play. Frontier Natural Resources is an independent natural gas producer focused on developing conventional and unconventional resources.
The scope of supply included a standardized LNGo solution consisting of four different modules, each handling one step of the liquefaction process. The whole LNGo system can be transported on eight trucks. It is deployed directly at the gas field and has a footprint of approximately 508 square meters, roughly the size of a basketball court. The Ten Man facility commenced production just four months from contract signing, and has produced approximately half a million liters of LNG in the first 20 days.
"This project demonstrates our unique capabilities to deliver innovative solutions for oil and gas applications that help our clients maximize the value of their assets," said Michael Walhof, sales director Distributed LNG Solutions for the Dresser-Rand business. "We are proud to provide Frontier Natural Resources with a reliable, robust solution to liquefy natural gas and cost-effectively move it to market."
The LNGo technology makes it possible to monetize stranded gas deposits due to its relatively low capital and operating costs. The micro-scale LNGo solution can be deployed in rough terrain or remote regions, eliminating the need to establish an expensive gas pipeline infrastructure or arrange for long-distance trucking of LNG from centralized plants to point of use. It can function as a decentralized solution where the requisite pipeline infrastructure is lacking, or as an onsite transformation solution to reduce or eliminate flaring of petroleum gas at, for example, oil rigs or producing gas fields.
Siemens AG is constructing a modern and sustainably designed Siemens Campus Erlangen in the southern part of the city of Erlangen, Germany. By 2030, the company's research center in the south of the city will have been transformed step-by-step into one of Siemens' most advanced locations worldwide. Future-oriented office, research and laboratory jobs will be located on the campus. Equipped with the most advanced building and energy technologies, it will be developed over the long term into Siemens' first CO
2-neutral location worldwide. A new urban residential and living environment will arise on the campus grounds. Siemens will be part of the community as never before. Designed by the Frankfurt architects KSP Jürgen Engel Architekten, the campus's open plan will link the company and society and provide a basis for the exchange of ideas.
The construction project has a planned investment volume of some €500 million and will cover an area of 54 hectares. Siemens Campus Erlangen underscores the company's long-term commitment to its Erlangen location and will be a symbol of innovative power for employees and for the region. The project was planned and designed in close cooperation with the state of Bavaria and the city of Erlangen.
Werner von Siemens, born on December 13, 1816, would have turned 200 years old this year. On November 29, Siemens was marking the anniversary of its company founder's birth by holding a gala event in the Mosaikhalle (Mosaic Hall) at its headquarters in Berlin. In addition to German Chancellor Angela Merkel, more than 100 prominent guests representing government, business, science, culture and the media were present. Joe Kaeser, President and CEO of Siemens AG, opened the ceremony. Nathalie von Siemens, a great-great-granddaughter of Werner von Siemens, Managing Director and spokesperson of the Board of Siemens Stiftung and a member of the Supervisory Board of Siemens AG, as well as Gerhard Cromme, Chairman of the company's Supervisory Board, will also gave speeches in honor of the company founder.
Together with Georg Halske, he established Telegraphen-Bauanstalt von Siemens & Halske, a company of international standing already within his lifetime. With inventions like the electric pointer telegraph, the electric generator and the world's first electric streetcar system, Werner von Siemens had a major influence on the technological development of today's world. His passion for engineering excellence and his relentless drive to create trailblazing innovations still shape the enterprise he founded. With around 351,000 employees in over 200 countries worldwide, Siemens AG is now a leading supplier in the growth fields of electrification, automation and digitalization.
The discovery of the dynamo-electric principle has brought about greater changes to the way our society lives than practically any other scientific breakthrough. By inventing the dynamo machine, not only did Werner von Siemens help bring about the advent of electrical machinery, he was also instrumental in accelerating and facilitating industrial processes. Seen from the perspective of society, this completely changed accepted concepts of time and mobility.
The Velaro D is the fourth generation of high-speed trains that Siemens has developed on the basis of the Velaro platform. Deutsche Bahn AG (DB) classifies the train as the new Series 407 ICE 3 (predecessors: Series 403 and Series 406 ICE 3). In December 2013, Germany's Federal Railway Authority (EBA) approved the trains' operation – also in multiple-unit or so-called double-traction mode – on the Deutsche Bahn rail network. Passenger operation started on December 21, 2013.
Authorization for operation in single-traction mode in France was granted in April 2015. Since June 2015 the trains have been travelling to Paris in regular passenger operation. In addition to Germany and France, the Velaro D is also intended for cross-border operation in Belgium.
Since 2007, trains based on the Velaro platform have operated with high reliability for more than one billion kilometers in China, Russia, Spain and Turkey – equal to roughly 25,000 times around the globe.
In various areas Siemens is committed to helping refugees. In spring 2015 the eight week internship program started and has now been extended to 14 locations. Siemens is also offering six-month special training courses. These courses encompass intensive language instruction as well as pre-vocational training in the areas of mechanics and electronics. The goal is to enable the participants to get an apprenticeship training position. Siemens Real Estate is making space available on a temporary basis at 15 different locations throughout Germany, among these locations are Munich and Erlangen. Countless employees all across Germany have also offered their help and participated in a wide range of donation and aid campaigns.
In May 2014 Siemens, together with the public utilities of Mainz, Linde and the RheinMain University of Applied Sciences, has laid the foundation stone for a new type of energy storage system. Now, time has come: By pressing a symbolic button, the Chairman of the Board of Linde Group, Dr. Wolfgang Büchele, Siemens board member Professor Siegfried Russwurm, two board members of Stadtwerke Mainz AG, Detlev Höhne and Dr. Tobias Brosze, and Professor Dr. Detlev Reymann, President of RheinMain University, officially launched a hydrogen production plant at the Energiepark Mainz on July 2, 2015. With the support of the German Federal Ministry of Economics and Technology as part of the Energy Storage Funding Initiative the 17-million-project could be realized. The system, equipped with an electrolyzer from Siemens, will convert surplus electricity from wind farms to hydrogen from now on. In this way, it will be possible to store electricity from renewable sources over longer periods of time. With a peak rating of up to 6 megawatts the plant is the largest of its kind in the world.
The principle of electrolysis has been tried and tested for decades. What is special about the Mainz system is that it involves highly dynamic PEM high-pressure electrolysis which is particularly suitable for high current density and can react within milliseconds to sharp increases in power generation from wind and solar sources. In this electrolyzer a proton exchange membrane (PEM) separates the two electrodes at which oxygen and hydrogen are formed. On the front and back of the membrane are precious-metal electrodes that are connected to the positive and negative poles of the voltage source. This is where the water is split. The system in Mainz will thus have a capacity relevant for bottlenecks in the grid and small wind farms.