engineer installations

инженерные сооружения

1) Military: engineer installations, engineer works, field works

2) Construction: engineering constructions, engineering structures, engineering works

оборонительное сооружение

1. defensive installation

противотанковое сооружение — countertank installation

долговременное сооружение — permanent installation

неплановое сооружение — incidental installation

подснежное сооружение — undersnow installation

инженерные сооружения — engineer installations

2. defensive works

общественные работы; общественные сооружения — public works

усовершенствованные полевые сооружения — deliberate works

гидротехническое сооружение — hydraulic engineering work

строительство сооружений — public works construction

речное регуляционное сооружение — river training work

дистанционное техническое обслуживание

1. remote sevice
2. remote maintenance

 

дистанционное техническое обслуживание
Техническое обслуживание объекта, проводимое под управлением персонала без его непосредственного присутствия.
[ОСТ 45.152-99 ]

Параллельные тексты EN-RU из ABB Review. Перевод компании Интент

Service from afar

Дистанционный сервис

ABB’s Remote Service concept is revolutionizing the robotics industry

Разработанная АББ концепция дистанционного обслуживания Remote Service революционизирует робототехнику

ABB robots are found in industrial applications everywhere – lifting, packing, grinding and welding, to name a few. Robust and tireless, they work around the clock and are critical to a company’s productivity. Thus, keeping these robots in top shape is essential – any failure can lead to serious output consequences. But what happens when a robot malfunctions?

Роботы АББ используются во всех отраслях промышленности для перемещения грузов, упаковки, шлифовки, сварки – всего и не перечислить. Надежные и неутомимые работники, способные трудиться день и ночь, они представляют большую ценность для владельца. Поэтому очень важно поддерживать их в надлежащей состоянии, ведь любой отказ может иметь серьезные последствия. Но что делать, если робот все-таки сломался?

ABB’s new Remote Service concept holds the answer: This approach enables a malfunctioning robot to alarm for help itself. An ABB service engineer then receives whole diagnostic information via wireless technology, analyzes the data on a Web site and responds with support in just minutes. This unique service is paying off for customers and ABB alike, and in the process is revolutionizing service thinking.

Ответом на этот вопрос стала новая концепция Remote Service от АББ, согласно которой неисправный робот сам просит о помощи. C помощью беспроводной технологии специалист сервисной службы АББ получает всю необходимую диагностическую информацию, анализирует данные на web-сайте и через считанные минуты выдает рекомендации по устранению отказа. Эта уникальная возможность одинаково ценна как для заказчиков, так и для самой компании АББ. В перспективе она способна в корне изменить весь подход к организации технического обслуживания.

Every minute of production downtime can have financially disastrous consequences for a company. Traditional reactive service is no longer sufficient since on-site service engineer visits also demand great amounts of time and money. Thus, companies not only require faster help from the service organization when needed but they also want to avoid disturbances in production.

Каждая минута простоя производства может привести к губительным финансовым последствиям. Традиционная организация сервиса, предусматривающая ликвидацию возникающих неисправностей, становится все менее эффективной, поскольку вызов сервисного инженера на место эксплуатации робота сопряжен с большими затратами времени и денег. Предприятия требуют от сервисной организации не только более быстрого оказания помощи, но и предотвращения возможных сбоев производства.

In 2006, ABB developed a new approach to better meet customer’s expectations: Using the latest technologies to reach the robots at customer sites around the world, ABB could support them remotely in just minutes, thereby reducing the need for site visits. Thus the new Remote Service concept was quickly brought to fruition and was launched in mid-2007. Statistics show that by using the system the majority of production stoppages can be avoided.

В 2006 г. компания АББ разработала новый подход к удовлетворению ожиданий своих заказчиков. Использование современных технологий позволяет специалистам АББ получать информацию от роботов из любой точки мира и в считанные минуты оказывать помощь дистанционно, в результате чего сокращается количество выездов на место установки. Запущенная в середине 2007 г. концепция Remote Service быстро себя оправдала. Статистика показывает, что её применение позволило предотвратить большое число остановок производства.

Reactive maintenance The hardware that makes ABB Remote Service possible consists of a communication unit, which has a function similar to that of an airplane’s so-called black box 1. This “service box” is connected to the robot’s control system and can read and transmit diagnostic information. The unit not only reads critical diagnostic information that enables immediate support in the event of a failure, but also makes it possible to monitor and analyze the robot’s condition, thereby proactively detecting the need for maintenance.

Устранение возникающих неисправностей Аппаратное устройство, с помощью которого реализуется концепция Remote Service, представляет собой коммуникационный блок, работающий аналогично черному ящику самолета (рис. 1). Этот блок считывает диагностические данные из контроллера робота и передает их по каналу GSM. Считывается не только информация, необходимая для оказания немедленной помощи в случае отказа, но и сведения, позволяющие контролировать и анализировать состояние робота для прогнозирования неисправностей и планирования технического обслуживания.

If the robot breaks down, the service box immediately stores the status of the robot, its historical data (as log files), and diagnostic parameters such as temperature and power supply. Equipped with a built-in modem and using the GSM network, the box transmits the data to a central server for analysis and presentation on a dedicated Web site. Alerts are automatically sent to the nearest of ABB’s 1,200 robot service engineers who then accesses the detailed data and error log to analyze the problem.

При поломке робота сервисный блок немедленно сохраняет данные о его состоянии, сведения из рабочего журнала, а также значения диагностических параметров (температура и характеристики питания). Эти данные передаются встроенным GSM-модемом на центральный сервер для анализа и представления на соответствующем web-сайте. Аварийные сообщения автоматически пересылаются ближайшему к месту аварии одному из 1200 сервисных инженеров-робототехников АББ, который получает доступ к детальной информации и журналу аварий для анализа возникшей проблемы.

A remotely based ABB engineer can then quickly identify the exact fault, offering rapid customer support. For problems that cannot be solved remotely, the service engineer can arrange for quick delivery of spare parts and visit the site to repair the robot. Even if the engineer must make a site visit, service is faster, more efficient and performed to a higher standard than otherwise possible.

Специалист АББ может дистанционно идентифицировать отказ и оказать быструю помощь заказчику. Если неисправность не может быть устранена дистанционно, сервисный инженер организовывает доставку запасных частей и выезд ремонтной бригады. Даже если необходимо разрешение проблемы на месте, предшествующая дистанционная диагностика позволяет минимизировать объем работ и сократить время простоя.

Remote Service enables engineers to “talk” to robots remotely and to utilize tools that enable smart, fast and automatic analysis. The system is based on a machine-to-machine (M2M) concept, which works automatically, requiring human input only for analysis and personalized customer recommendations. ABB was recognized for this innovative solution at the M2M United Conference in Chicago in 2008 Factbox.

Remote Service позволяет инженерам «разговаривать» с роботами на расстоянии и предоставляет в их распоряжение интеллектуальные средства быстрого автоматизированного анализа. Система основана на основе технологии автоматической связи машины с машиной (M2M), где участие человека сводится к анализу данных и выдаче рекомендаций клиенту. В 2008 г. это инновационное решение от АББ получило приз на конференции M2M United Conference в Чикаго (см. вставку).

Proactive maintenance 

Remote Service also allows ABB engineers to monitor and detect potential problems in the robot system and opens up new possibilities for proactive maintenance.

Прогнозирование неисправностей

Remote Service позволяет инженерам АББ дистанционно контролировать состояние роботов и прогнозировать возможные неисправности, что открывает новые возможности по организации профилактического обслуживания.

The service box regularly takes condition measurements. By monitoring key parameters over time, Remote Service can identify potential failures and when necessary notify both the end customer and the appropriate ABB engineer. The management and storage of full system backups is a very powerful service to help recover from critical situations caused, for example, by operator errors.

Сервисный блок регулярно выполняет диагностические измерения. Непрерывно контролируя ключевые параметры, Remote Service может распознать потенциальные опасности и, при необходимости, оповещать владельца оборудования и соответствующего специалиста АББ. Резервирование данных для возможного отката является мощным средством, обеспечивающим восстановление системы в критических ситуациях, например, после ошибки оператора.

The first Remote Service installation took place in the automotive industry in the United States and quickly proved its value. The motherboard in a robot cabinet overheated and the rise in temperature triggered an alarm via Remote Service. Because of the alarm, engineers were able to replace a faulty fan, preventing a costly production shutdown.

Первая система Remote Service была установлена на автозаводе в США и очень скоро была оценена по достоинству. Она обнаружила перегрев материнской платы в шкафу управления роботом и передала сигнал о превышении допустимой температуры, благодаря чему инженеры смогли заменить неисправный вентилятор и предотвратить дорогостоящую остановку производства.

MyRobot: 24-hour remote access

Having regular access to a robot’s condition data is also essential to achieving lean production. At any time, from any location, customers can verify their robots’ status and access maintenance information and performance reports simply by logging in to ABB’s MyRobot Web site. The service enables customers to easily compare performances, identify bottlenecks or developing issues, and initiate the most

Сайт MyRobot: круглосуточный дистанционный доступ

Для того чтобы обеспечить бесперебойное производство, необходимо иметь регулярный доступ к информации о состоянии робота. Зайдя на соответствующую страницу сайта MyRobot компании АББ, заказчики получат все необходимые данные, включая сведения о техническом обслуживании и отчеты о производительности своего робота. Эта услуга позволяет легко сравнивать данные о производительности, обнаруживать возможные проблемы, а также оптимизировать планирование технического обслуживания и модернизации. С помощью MyRobot можно значительно увеличить выпуск продукции и уменьшить количество выбросов.

Award-winning solution

In June 2008, the innovative Remote Service solution won the Gold Value Chain award at the M2M United Conference in Chicago. The value chain award honors successful corporate adopters of M2M (machine–to-machine) technology and highlights the process of combining multiple technologies to deliver high-quality services to customers. ABB won in the categoryof Smart Services.

Приз за удачное решение

В июне 2008 г. инновационное решение Remote Service получило награду Gold Value Chain (Золотая цепь) на конференции M2M United Conference в Чикаго. «Золотая цепь» присуждается за успешное масштабное внедрение технологии M2M (машина – машина), а также за достижения в объединении различных технологий для предоставления высококачественных услуг заказчикам. АББ одержала победу в номинации «Интеллектуальный сервис».

Case study: Tetley Tetley GB Ltd is the world’s second-largest manufacturer and distributor of tea. The company’s manufacturing and distribution business is spread across 40 countries and sells over 60 branded tea bags. Tetley’s UK tea production facility in Eaglescliffe, County Durham is the sole producer of Tetley tea bags 2.

Пример применения: Tetley Компания TetleyGB Ltd является вторым по величине мировым производителем и поставщиком чая. Производственные и торговые филиалы компании имеются в 40 странах, а продукция распространяется под 60 торговыми марками. Чаеразвесочная фабрика в Иглсклифф, графство Дарем, Великобритания – единственный производитель чая Tetley в пакетиках (рис. 2).

ABB offers a flexible choice of service agreements for both new and existing robot installations, which can help extend the mean time between failures, shorten the time to repair and lower the cost of automated production.

Предлагаемые АББ контракты на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и общую стоимость автоматизированного производства.

Robots in the plant’s production line were tripping alarms and delaying the whole production cycle. The spurious alarms resulted in much unnecessary downtime that was spent resetting the robots in the hope that another breakdown could be avoided. Each time an alarm was tripped, several hours of production time was lost. “It was for this reason that we were keen to try out ABB’s Remote Service agreement,” said Colin Trevor, plant maintenance manager.

Установленные в технологической линии роботы выдавали аварийные сигналы, задерживающие выполнение производственного цикла. Ложные срабатывания вынуждали перезапускать роботов в надежде предотвратить возможные отказы, в результате чего после каждого аварийного сигнала производство останавливалось на несколько часов. «Именно поэтому мы решили попробовать заключить с АББ контракт на дистанционное техническое обслуживание», – сказал Колин Тревор, начальник технической службы фабрики.

To prevent future disruptions caused by unplanned downtime, Tetley signed an ABB Response Package service agreement, which included installing a service box and system infrastructure into the robot control systems. Using the Remote Service solution, ABB remotely monitors and collects data on the “wear and tear” and productivity of the robotic cells; this data is then shared with the customer and contributes to smooth-running production cycles.

Для предотвращения ущерба в результате незапланированных простоев Tetley заключила с АББ контракт на комплексное обслуживание Response Package, согласно которому системы управления роботами были дооборудованы сервисными блоками с необходимой инфраструктурой. С помощью Remote Service компания АББ дистанционно собирает данные о наработке, износе и производительности роботизированных модулей. Эти данные предоставляются заказчику для оптимизации загрузки производственного оборудования.

Higher production uptime

Since the implementation of Remote Service, Tetley has enjoyed greatly reduced robot downtime, with no further disruptions caused by unforeseen problems. “The Remote Service package has dramatically changed the plant,” said Trevor. “We no longer have breakdown issues throughout the shift, helping us to achieve much longer periods of robot uptime. As we have learned, world-class manufacturing facilities need world-class support packages. Remote monitoring of our robots helps us to maintain machine uptime, prevent costly downtime and ensures my employees can be put to more valuable use.”

Увеличение полезного времени

С момента внедрения Remote Service компания Tetley была приятно удивлена резким сокращением простоя роботов и отсутствием незапланированных остановок производства. «Пакет Remote Service резко изменил ситуацию на предприятии», – сказал Тревор. «Мы избавились от простоев роботов и смогли резко увеличить их эксплуатационную готовность. Мы поняли, что для производственного оборудования мирового класса необходим сервисный пакет мирового класса. Дистанционный контроль роботов помогает нам поддерживать их в рабочем состоянии, предотвращать дорогостоящие простои и задействовать наш персонал для выполнения более важных задач».

Service access

Remote Service is available worldwide, connecting more than 500 robots. Companies that have up to 30 robots are often good candidates for the Remote Service offering, as they usually have neither the engineers nor the requisite skills to deal with robotics faults themselves. Larger companies are also enthusiastic about Remote Service, as the proactive services will improve the lifetime of their equipment and increase overall production uptime.

Доступность сервиса

Сеть Remote Service охватывает более 700 роботов по всему миру. Потенциальными заказчиками Remote Service являются компании, имеющие до 30 роботов, но не имеющие инженеров и техников, способных самостоятельно устранять их неисправности. Интерес к Remote Service проявляют и более крупные компании, поскольку они заинтересованы в увеличении срока службы и эксплуатационной готовности производственного оборудования.

In today’s competitive environment, business profitability often relies on demanding production schedules that do not always leave time for exhaustive or repeated equipment health checks. ABB’s Remote Service agreements are designed to monitor its customers’ robots to identify when problems are likely to occur and ensure that help is dispatched before the problem can escalate. In over 60 percent of ABB’s service calls, its robots can be brought back online remotely, without further intervention.

В условиях современной конкуренции окупаемость бизнеса часто зависит от соблюдения жестких графиков производства, не оставляющих времени для полномасштабных или периодических проверок исправности оборудования. Контракт Remote Service предусматривает мониторинг состояния роботов заказчика для прогнозирования возможных неисправностей и принятие мер по их предотвращению. В более чем 60 % случаев для устранения неисправности достаточно дистанционной консультации в сервисной службе АББ, дальнейшего вмешательства не требуется.

ABB offers a flexible choice of service agreements for both new and existing robot installations, which helps extend the mean time between failures, shorten the time to repair and lower the total cost of ownership. With four new packages available – Support, Response, Maintenance and Warranty, each backed up by ABB’s Remote Service technology – businesses can minimize the impact of unplanned downtime and achieve improved production-line efficiency.

Компания АББ предлагает гибкий выбор контрактов на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, которые позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и эксплуатационные расходы. Четыре новых пакета на основе технологии Remote Service – Support, Response, Maintenance и Warranty – позволяют минимизировать внеплановые простои и значительно повысить эффективность производства.

The benefits of Remote Sevice are clear: improved availability, fewer service visits, lower maintenance costs and maximized total cost of ownership. This unique service sets ABB apart from its competitors and is the beginning of a revolution in service thinking. It provides ABB with a great opportunity to improve customer access to its expertise and develop more advanced services worldwide.

Преимущества дистанционного технического обслуживания очевидны: повышенная надежность, уменьшение выездов ремонтных бригад, уменьшение затрат на обслуживание и общих эксплуатационных расходов. Эта уникальная услуга дает компании АББ преимущества над конкурентами и демонстрирует революционный подход к организации сервиса. Благодаря ей компания АББ расширяет доступ заказчиков к опыту своих специалистов и получает возможность более эффективного оказания технической помощи по всему миру.

Тематики

• тех. обсл. и ремонт средств электросвязи

Обобщающие термины

• виды технического обслуживания и ремонта

EN

• remote maintenance
• remote sevice

Русско-английский словарь нормативно-технической терминологии > дистанционное техническое обслуживание

инженер по монтажу оборудования

installation engineer

техник по холодильному оборудованию — refrigeration engineer

оборудование для печатания журналов — magazine installations

противопожарное оборудование — fire-fighting installation

радиоэлектронное оборудование — electronic installation

оборудование для печатания газет — news installations

Brotan, Johann

SUBJECT AREA: Railways and locomotives

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b. 24 June 1843 Kattau, Bohemia (now in the Czech Republic)

d. 20 November 1923 Vienna, Austria

[br]

Czech engineer, pioneer of the watertube firebox for steam locomotive boilers.

[br]

Brotan, who was Chief Engineer of the main workshops of the Royal Austrian State Railways at Gmund, found that locomotive inner fireboxes of the usual type were both expensive, because the copper from which they were made had to be imported, and short-lived, because of corrosion resulting from the use of coal with high sulphur content. He designed a firebox of which the side and rear walls comprised rows of vertical watertubes, expanded at their lower ends into a tubular foundation ring and at the top into a longitudinal water/steam drum. This projected forward above the boiler barrel (which was of the usual firetube type, though of small diameter), to which it was connected. Copper plates were eliminated, as were firebox stays.

The first boiler to incorporate a Brotan firebox was built at Gmund under the inventor's supervision and replaced the earlier boiler of a 0−6−0 in 1901. The increased radiantly heated surface was found to produce a boiler with very good steaming qualities, while the working pressure too could be increased, with consequent fuel economies. Further locomotives in Austria and, experimentally, elsewhere were equipped with Brotan boilers.

Disadvantages of the boiler were the necessity of keeping the tubes clear of scale, and a degree of structural weakness. The Swiss engineer E. Deffner improved the latter aspect by eliminating the forward extension of the water/steam drum, replacing it with a large-diameter boiler barrel with the rear section of tapered wagon-top type so that the front of the water/steam drum could be joined directly to the rear tubeplate. The first locomotives to be fitted with this Brotan-Deffner boiler were two 4−6−0s for the Swiss Federal Railways in 1908 and showed very favourable results. However, steam locomotive development ceased in Switzerland a few years later in favour of electrification, but boilers of the Brotan-Deffner type and further developments of it were used in many other European countries, notably Hungary, where more than 1,000 were built. They were also used experimentally in the USA: for instance, Samuel Vauclain, as President of Baldwin Locomotive Works, sent his senior design engineer to study Hungarian experience and then had a high-powered 4−8−0 built with a watertube firebox. On stationary test this produced the very high figure of 4,515 ihp (3,370 kW), but further development work was frustrated by the trade depression commencing in 1929. In France, Gaston du Bousquet had obtained good results from experimental installations of Brotan-Deffner-type boilers, and incorporated one into one of his high-powered 4−6−4s of 1910. Experiments were terminated suddenly by his death, followed by the First World War, but thirty-five years later André Chapelon proposed using a watertube firebox to obtain the high pressure needed for a triple-expansion, high-powered, steam locomotive, development of which was overtaken by electrification.

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Further Reading

G.Szontagh, 1991, "Brotan and Brotan-Deffner type fireboxes and boilers applied to steam locomotives", Transactions of the Newcomen Society 62 (an authoritative account of Brotan boilers).

PJGR

Wallace, Sir William

SUBJECT AREA: Ports and shipping

[br]

b. 25 August 1881 Leicester, England

d. 27 May 1963 Edinburgh, Scotland

[br]

English engineer; developer of the Denny-Brown fin stabilizer for ships.

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Wallace was brought up just outside Glasgow, and educated at Paisley Grammar School and later at the Anderson College in Glasgow. The next few years were typical of the early years in the life of many young engineers: he served an apprenticeship at the Paisley shipyard of Bow, MacLachlan, before joining the British and Burmese Steam Navigation Company (Paddy Henderson's Line) as a junior engineer. After some years on the Glasgow to Rangoon service, he rose to the rank of Chief Engineer early in life and then came ashore in 1911.

He joined the old established Edinburgh engineering company of Brown Brothers as a draughtsman, but by 1917 had been promoted Managing Director. He was appointed Chairman in 1946. During his near thirty years at the helm, he experimented widely and was the engineering force behind the development of the Denny-Brown ship stabilizer which was jointly pursued by Brown Brothers and the Dumbarton shipyard of William Denny \& Brothers. The first important installation was on the cross-channel steamer Isle of Sark, built at Dumbarton for the Southern Railway in 1932. Over the years countless thousands of these installations have been fitted on liners, warships and luxury yachts. Brown Brothers produced many other important engineering innovations at this time, including the steam catapult for aircraft carriers.

In later years Sir William (now knighted) took an active part in the cultural life of Edinburgh and of Scotland. From 1952 to 1954 he served as President of the Institution of Engineers and Shipbuilders in Scotland.

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Principal Honours and Distinctions

Knighted 1951. CBE 1944. Fellow of the Royal Society of Edinburgh. President, Institution of Engineers and Shipbuilders in Scotland 1952–4; Gold Medal.

Bibliography

1954–5 "Experiences in the stabilization of ships", Transactions of the Institution of Engineers and Shipbuilders in Scotland 98:197–266.

FMW

терминальное оборудование

1. terminal hardware

голое оборудование — bare hardware

аппаратное оборудование — hardware

заказное оборудование — custom hardware

сетевое оборудование — networking hardware

оконечное ВЧ оборудование — carrier terminal

2. data terminal equipment

ВЧ оборудование — carrier equipment

оборудования — equipment facilities

парк оборудования — equipment stock

склад оборудования — equipment park

оборудование ввода — input equipment

3. terminal equipment

промышленное оборудование — industrial equipment

сваебойное оборудование — pile-driving equipment

серийное оборудование — production run equipment

списание оборудования — equipment final disposal

тарное оборудование — paper converting equipment

4. terminal installations

инженерное оборудование зданий — plumbing installation

оборудование для печатания газет — news installations

инженер по монтажу оборудования — installation engineer

радиоэлектронное оборудование — electronic installation

противопожарное оборудование — fire-fighting installation

Brown, Charles Eugene Lancelot

SUBJECT AREA: Electricity, Public utilities, Railways and locomotives

[br]

b. 17 June 1863 Winterthur, Switzerland

d. 2 May 1924 Montagnola, Italy

[br]

English engineer who developed polyphase electrical generation and transmission plant.

[br]

After attending the Technical College in Winterthur, Brown served with Emile Burgin in Basle before entering the Oerlikon engineering works near Zurich. Two years later he became Director of the electrical department of Oerlikon and from that time was involved in the development of electrical equipment for the generation and distribution of power. The Lauffen-Frankfurt 110-mile (177 km) transmission line of 1891 demonstrated the commercial feasibility of transmitting electrical power over great distances with three-phase alternating current. For this he designed a generator and early examples of oil-cooled transformers, and the scheme gave an impetus to the development of electric-power transmission throughout Europe. In 1891, in association with Walter Boveri, Brown founded the works of Brown Boveri \& Co. at Baden, Switzerland, and until his retirement in 1911 he devoted his energies to the design of polyphase alternating-current machinery. Important installations included the Frankfurt electricity works (1894), the Paderno-Milan transmission line, and the Lugano tramway of 1894, the first system in Europe to use three-phase traction motors. This tramway was followed by many other polyphase and mountain railways. The acquisition by Brown Boveri \& Co. in 1900 of the manufacturing rights of the Parsons steam turbine directed Brown's attention to problems associated with high-speed machines. Recognizing the high centrifugal stress involved, he began to employ solid cylindrical generator rotors with slots for the excitation winding, a method that has come to be universally adopted in large alternators.

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Bibliography

3 December 1901, British patent no. 24,632 (slotted rotor for alternators).

Further Reading

Obituary, 1924, The Engineer 137:543.

Ake T.Vrenthem, 1980, Jonas Wenstrom and the Three Phase System, Stockholm, pp. 26–8 (obituary).

75 Years of Brown Boveri, 1966, Baden, Switzerland (for a company history).

GW

Poulsen, Valdemar

SUBJECT AREA: Broadcasting, Electronics and information technology, Recording, Telecommunications

[br]

b. 23 November 1869 Copenhagen, Denmark

d. 23 July 1942 Gentofte, Denmark

[br]

Danish engineer who developed practical magnetic recording and the arc generator for continuous radio waves.

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From an early age he was absorbed by phenomena of physics to the exclusion of all other subjects, including mathematics. When choosing his subjects for the final three years in Borgedydskolen in Christianshavn (Copenhagen) before university, he opted for languages and history. At the University of Copenhagen he embarked on the study of medicine in 1889, but broke it off and was apprenticed to the machine firm of A/S Frichs Eftf. in Aarhus. He was employed between 1893 and 1899 as a mechanic and assistant in the laboratory of the Copenhagen Telephone Company KTAS. Eventually he advanced to be Head of the line fault department. This suited his desire for experiment and measurement perfectly. After the invention of the telegraphone in 1898, he left the laboratory and with responsible business people he created Aktieselskabet Telegrafonen, Patent Poulsen in order to develop it further, together with Peder Oluf Pedersen (1874– 1941). Pedersen brought with him the mathematical background which eventually led to his professorship in electronic engineering in 1922.

The telegraphone was the basis for multinational industrial endeavours after it was demonstrated at the 1900 World's Exhibition in Paris. It must be said that its strength was also its weakness, because the telegraphone was unique in bringing sound recording and reproduction to the telephone field, but the lack of electronic amplifiers delayed its use outside this and the dictation fields (where headphones could be used) until the 1920s. However, commercial interest was great enough to provoke a number of court cases concerning patent infringement, in which Poulsen frequently figured as a witness.

In 1903–4 Poulsen and Pedersen developed the arc generator for continuous radio waves which was used worldwide for radio transmitters in competition with Marconi's spark-generating system. The inspiration for this work came from the research by William Duddell on the musical arc. Whereas Duddell had proposed the use of the oscillations generated in his electric arc for telegraphy in his 1901 UK patent, Poulsen contributed a chamber of hydrogen and a transverse magnetic field which increased the efficiency remarkably. He filed patent applications on these constructions from 1902 and the first publication in a scientific forum took place at the International Electrical Congress in St Louis, Missouri, in 1904.

In order to use continuous waves efficiently (the high frequency constituted a carrier), Poulsen developed both a modulator for telegraphy and a detector for the carrier wave. The modulator was such that even the more primitive spark-communication receivers could be used. Later Poulsen and Pedersen developed frequency-shift keying.

The Amalgamated Radio-Telegraph Company Ltd was launched in London in 1906, combining the developments of Poulsen and those of De Forest Wireless Telegraph Syndicate. Poulsen contributed his English and American patents. When this company was liquidated in 1908, its assets were taken over by Det Kontinentale Syndikat for Poulsen Radio Telegrafi, A/S in Copenhagen (liquidated 1930–1). Some of the patents had been sold to C.Lorenz AG in Berlin, which was very active.

The arc transmitting system was in use worldwide from about 1910 to 1925, and the power increased from 12 kW to 1,000 kW. In 1921 an exceptional transmitter rated at 1,800 kW was erected on Java for communications with the Netherlands. More than one thousand installations had been in use worldwide. The competing systems were initially spark transmitters (Marconi) and later rotary converters ( Westinghouse). Similar power was available from valve transmitters only much later.

From c. 1912 Poulsen did not contribute actively to further development. He led a life as a well-respected engineer and scientist and served on several committees. He had his private laboratory and made experiments in the composition of matter and certain resonance phenomena; however, nothing was published. It has recently been suggested that Poulsen could not have been unaware of Oberlin Smith's work and publication in 1888, but his extreme honesty in technical matters indicates that his development was indeed independent. In the case of the arc generator, Poulsen was always extremely frank about the inspiration he gained from earlier developers' work.

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Bibliography

1899, British patent no. 8,961 (the first British telegraphone patent). 1903, British patent no. 15,599 (the first British arc-genera tor patent).

His scientific publications are few, but fundamental accounts of his contribution are: 1900, "Das Telegraphon", Ann. d. Physik 3:754–60; 1904, "System for producing continuous oscillations", Trans. Int. El. Congr. St. Louis, Vol. II, pp. 963–71.

Further Reading

A.Larsen, 1950, Telegrafonen og den Traadløse, Ingeniørvidenskabelige Skrifter no. 2, Copenhagen (provides a very complete, although somewhat confusing, account of Poulsen's contributions; a list of his patents is given on pp. 285–93).

F.K.Engel, 1990, Documents on the Invention of Magnetic Re cor ding in 1878, New York: Audio Engineering Society, reprint no. 2,914 (G2) (it is here that doubt is expressed about whether Poulsen's ideas were developed independently).

GB-N

стационарное оборудование

fixed installation

инженерное оборудование зданий — plumbing installation

оборудование для печатания газет — news installations

инженер по монтажу оборудования — installation engineer

радиоэлектронное оборудование — electronic installation

закрепленное, стационарное оборудование — fixed equipment

Eiffel, Alexandre Gustave

SUBJECT AREA: Civil engineering

[br]

b. 15 December 1832 Dijon, France

d. 27 December 1923 Paris, France

[br]

French engineer, best known for the famous tower in Paris that bears his name.

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During his long life Eiffel, together with a number of architects, was responsible for the design and construction of a wide variety of bridges, viaducts, harbour installations, exhibition halls, galleries and department stores; he set up his own firm in 1867 to handle such construction. Of particular note were his great arched bridges, such as the 530 ft (162 m) span arch over the River Douro at Oporto in Portugal (1877–9) and the 550 ft (168 m) span of the Pont de Garabit over the Truyère in France (1880–4). He was responsible in 1884 for the protective iron-work for the Statue of Liberty in New York and, a year later, for the great dome over the Nice Observatory. In 1876 he had collaborated with Boileau to build the Bon Marché department store in Paris. The predominant material for all these structures was iron, and, in some cases glass was important. The famous Eiffel Tower in Paris is entirely of wrought iron, and the legs are supported on masonry piers that are each set into concrete beneath the ground. The idea of the tower was first conceived in 1884 by Maurice Koechlin and Emile Nougier, and Eiffel won a competition for the commission to built the structure. His imaginative and practical scheme was for a strong lightweight construction 984 ft (300 m) high, with its 12,000 sections to be prefabricated and riveted together largely before erection; the open, perforated design reduced the problems of wind resistance. The tower was constructed on schedule by 1889 to commemorate the centenary of the outbreak of the French Revolution and was the tallest structure in the world until the erection of the Empire State Building in New York in 1930–2.

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Further Reading

J.Harriss, 1975, The Tallest Tower: Eiffel and the Belle Epoque, Boston: Hough ton Mifflin.

F.Poncetton, 1939, Eiffel: Le Magicien du Fer, Paris: Tournelle.

DY

Pounder, Cuthbert Coulson

SUBJECT AREA: Ports and shipping, Steam and internal combustion engines

[br]

b. 10 May 1891 Hartlepool, England

d. 18 December 1982 Belfast (?), Northern Ireland

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English marine engineer and exponent of the slow-speed diesel engine.

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Pounder served an apprenticeship with Richardsons Westgarth, marine engineers in north east England. Shortly after, he moved to Harland \& Wolff of Belfast and there fulfilled his life's work. He rose to the rank of Director but is remembered for his outstanding leadership in producing the most advanced steam and diesel machinery installations of their time. Harland \& Wolff were the main licensees for the Burmeister \& Wain marine diesel system, and the Copenhagen company made most of the decisions on design; however, Pounder often found himself in the hot seat and once had the responsibility of concurring with the shipyard's decision to build three Atlantic liners with the largest diesel engines in the world, well beyond the accepted safe levels of extrapolation. With this, Belfast secured worldwide recognition as builders of diesel-driven liners. During the German occupation of Denmark (1940–5), the engineering department at Belfast worked on its own and through systematic research and experimentation built up a database of information that was invaluable in the postwar years.

Pounder was instrumental in the development of airless injection diesel fuel pumps. He was a stalwart supporter of all research and development, and while at Belfast was involved in the building of twelve hundred power units. While in his twenties, Pounder began a literary career which continued for sixty years. The bulk of his books and papers were on engineering and arguably the best known is his work on marine diesel engines, which ran to many editions. He was Chairman of Pametrada, the marine engineering research council of Great Britain, and later of the machinery committee of the British Ship Research Association. He regarded good relations within the industry as a matter of paramount importance.

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Principal Honours and Distinctions

President, Institute of Marine Engineers; Denny Gold Medal 1839, 1959. Institution of Mechanical Engineers Ackroyd Stewart Award; James Clay ton Award.

Further Reading

Michael Moss and John R.Hume, 1986, Shipbuilders to the World, Belfast: Blackstaff.

FMW

Rittinger, Peter von

SUBJECT AREA: Mining and extraction technology

[br]

b. 23 January 1811 Neutitschein, Moravia (now Now Jicin, Czech Republic)

d. 7 December 1872 Vienna, Austria

[br]

Austrian mining engineer, improver of the processing of minerals.

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After studying law, philosophy and politics at the University of Olmutz (now Olomouc), in 1835 Rittinger became a fellow of the Mining Academy in Schemnitz (now Banská Štiavnica), Slovakia. In 1839, the year he finished at the academy, he published a book on perspective drawing. The following year, he became Inspector of Mills at the ore mines in Schemnitz, and in 1845 he was engaged in coal mining in Bohemia and Moravia. In 1849 he joined the mining administration at Joachimsthal (now Jáchymov), Bohemia. In these early years he contributed his first important innovations for the mining industry and thus fostered his career in the government's service. In 1850 he was called to Vienna to become a high-ranked officer in various ministries. He was responsible for the construction of buildings, pumping installations and all sorts of machinery in the mining industry; he reorganized the curricula of the mining schools, was responsible for the mint and became head of the department of mines, forests and salt-works in the Austrian empire.

During all his years of public service, Rittinger continued his concern with technological innovations. He improved the processing of ores by introducing in 1844 the rotary washer and the box classifier, and later his continuously shaking concussion table which, having been exhibited at the Vienna World Fair of 1873, was soon adopted in other countries. He constructed water-column pumps, invented a differential shaft pump with hydraulic linkage to replace the heavy iron rods and worked on centrifugal pumps. He was one of the first to be concerned with the transfer of heat, and he developed a system of using exhaust steam for heating in salt-works. He kept his eye on current developments abroad, using his function as official Austrian commissioner to the world exhibitions, on which he published frequently as well as on other matters related to technology. With his systematic handbook on mineral processing, first published in 1867, he emphasized his international reputation in this specialized field of mining.

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Principal Honours and Distinctions

Knighted 1863. Order of the Iron Crown 1863. Honorary Citizen of Joachimsthal 1864. President, Austrian Chamber of Engineers and Architects 1863–5.

Bibliography

1849, Der Spitzkasten-Apparat statt Mehlrinnen und Sümpfen…bei der nassen Aufbereitung, Freiberg.

1854, Theoretisch-praktische Anleitung zur Rader-Verzahnung, Vienna.

1855, Theoretisch-praktische Abhandlung über ein für alle Gattungen von Flüssigkeiten anwendbares neues Abdampfverfahren, Vienna.

1861, Theorie und Bau der Rohrturbinen, Prague.

1867, Lehrbuch der Aufbereitungskunde, Berlin (with supplements, 1870–73).

Further Reading

H.Kunnert, 1972, "Peter Ritter von Rittinger. Lebensbild eines grossen Montanisten", Der Anschnitt 24:3–7 (a detailed description of his life, based on source material).

J.Steiner, 1972, "Der Beitrag von Peter Rittinger zur Entwicklung der Aufbereitungstechnik". Berg-und hüttenmännische Monatshefte 117: 471–6 (an evaluation of Rittinger's achievements for the processing of ores).

WK