The TELEFUNKEN 2038L is a 19 inches B/W television with VHF and UHF Channels selectors. Other knobs are volume/on-off switch, tone,bright,contrast.
- Tuning is obtained with rotatable drum selectors for VHF channels (A,B,C,D,E,F,G,.........) and variable rotatable capacitor for UHF which is transistorized.
- The prior UHF tuner art has invariably resorted to a continuous
type tuner for receivers designed to accommodate the entire UHF band.
The frequency determining circuits for such tuners, however, pose
special design problems since conventional lumped constant circuit
elements, which ordinarily suffice at VHF, do not function properly at
UHF. This is due to the fact that the physical dimensions of such
components become an appreciable fraction of the wavelength of UHF
signals, and particularly is this the case in the upper reaches of the
UHF band. This, in turn, dictates recourse to distributed constant
elements, such as tunable transmission lines, for use in the frequency
determining circuits.
A conventional tuned-line UHF tuner of the type above-mentioned comprises one or more RF preselector stages, a vacuum tube oscillator stage and a mixer circuit which develops an IF or difference frequency signal by heterodyning a selected RF signal with the oscillator signal.
To feed RF signals a VHF UHF 300 OHM RF Demixer Splitter was used from 75 OHM Aerial from 75 ohm to two 300 ohm uhf / vhf band. (see pictures)
This separator converts a 75 ohm incoming signal from 75 ohm antenna into to two 300 ohm outgoing signal to tv and matches impedance between 75 ohm coaxial cable and 300 ohm tv and antenna inputs. it separates the three signals from the 3-way antenna into individual signals for uhf, vhf and fm. two outputs connect to the uhf, vhf antenna terminals on rear of the tv set. separate screw terminals connects 300 ohm twin lead to the fm receivers.
- A rotatable drum containing twelve pre-defined channel-specific filters determines the received channel, where the inductors of the input matching, the channel filter and the LO tank circuit are changed. The tuner is divided into two chambers for maximum isolation between the sensitive RF input and the mixer-oscillator-IF section with its much larger signals. Also on the drum there are eventually two separate sub-modules.
- It's completely based on tubes technology.
With this concept, which essentially turned the tuner module into a kind of Lego building block construction, many different tuners became possible. Depending upon the country of destination and its associated standard and IF settings, the required filter modules would be selected. Service workshops and tv fabricants could later even add or exchange modules when new channels were introduced, since every inductor module had its individual factory code and could be ordered separately. As a consequence more versions of the tuner were produced, covering at least standards B, B-for-Italy, C. E, F and M.
- Back the usual controls for synchronizations and picture height and amplitude.
Telefunken (WAS)
is a German radio and television apparatus company, founded in 1903,
in Berlin, as a joint venture of two large companies, Siemens &
Halske (S & H) and the Allgemeine Elektricitäts-Gesellschaft
(General Electricity Company).
The name "Telefunken" appears in:
* the product brand name "Telefunken";
* AEG subsidiary as Telefunken GmbH in 1955;
* AEG subsidiary as Telefunken AG in 1963;
* company merged as AEG-Telefunken (1967–1985);
* the company "Telefunken USA" (2001). Now Telefunken Elektroakustik (2009)
* the company "Telefunken semiconductor GmbH & Co KG" Heilbronn Germany (2009).
* the company "Telefunken Lighting technologies S,L" (2009)
The
company Telefunken USA[1] was incorporated in early 2001 to provide
restoration services and build reproductions of vintage Telefunken
microphones.
Around
the turn of the 20th century, two groups of German researchers worked
on the development of techniques for wireless communication. The one
group at AEG, led by Adolf Slaby and Georg Graf von Arco, developed
systems for the German navy; the other one, under Karl Ferdinand Braun,
at Siemens, for the German army.
When
a dispute concerning patents arose between the two companies, Kaiser
Wilhelm II decided that the two companies were to be joined, creating on
27 May 1903 the company Gesellschaft für drahtlose Telegraphie System
Telefunken ("The Company for Wireless Telegraphy Ltd."), and the
disputed patents and techniques were invested in it. This was then
renamed on 17 April 1923 as Telefunken, The Company for Wireless
Telegraphy. Telefunken was the company's telegraph address. The first
technical director of Telefunken was George Graf von Arco.
Starting in 1923, Telefunken built broadcast transmitters and radio sets.
In
1928, Telefunken made history by designing the V-41 amplifier for the
German Radio Network. This was the very first two stage, "Hi-Fi"
amplifier which began a chapter in recording history. Over time,
Telefunken perfected their designs and in 1950 the V-72 amplifier was
born. The TAB (a manufacturing subcontractor to Telefunken) V-72 soon
became popular with other radio stations and recording facilities and
would eventually come to help define the sound of most European
recordings. The V-72S was the only type of amplifier found in the
legendary REDD-37 console used by the Beatles at Abbey Road Studios on
every recording prior to Rubber Soul. Today the V-72 is still the most
sought after example of Telefunken's design and over 50 years later
continues to be the benchmark by which all other tube based microphone
preamplifiers are measured. In 1932, record players were added to the
product line.
In
1941 Siemens transferred its Telefunken shares to AEG as part of the
agreements known as the "Telefunken settlement", and AEG thus became the
sole owner and continued to lead Telefunken as a subsidiary (starting
in 1955 as "Telefunken GmbH" and from 1963 as "Telefunken AG").
During
the Second World War Telefunken was a supplier of vacuum tubes,
transmitters and radio relay systems, and developed radar facilities and
directional finders, aiding extensively to the German air defense
against British-American Aerial Bombing. During the war, manufacturing
plants were shifted to and developed in West Germany or relocated. Thus,
Telefunken, under AEG, turned into the smaller subsidiary, with the
three divisions realigning and data processing technology, elements as
well as broadcast, television and phono. Telefunken had substantial
successes in these markets during the time of self-sufficiency and also
later in the AEG company. Telefunken was also the originator of the FM
radio broadcast system. Telefunken, through the subsidiary company
Teldec (a joint venture with Decca Records), was for many decades one of
the largest German record companies, until Teldec was sold to WEA in
1988.
In
1959, Telefunken established a modern semiconductor works in
Heilbronn, where in April 1960 production began. The works was expanded
several times, and in 1970 a new 6-storey building was built at the
northern edge of the area. At the beginning of the 1970s it housed
approximately 2,500 employees.
In
1967, Telefunken was merged with AEG, which was then renamed to
AEG-Telefunken. During this era, Walter Bruch developed the PAL color
television for the company, in use by most countries outside the
Americas today (i.e. United Kingdom - PAL-I), and by Brazil (PAL-M) and
Argentina (PAL-N) in South America.
The
mainframe computer TR 4 was developed at Telefunken in Backnang, and
the TR 440 model was developed at Telefunken in Konstanz. They were in
use at many German university computing centres from the 1970s to around
1985. The development and manufacture of large computers was separated
in 1974 to the Konstanz Computer Company (CGK). The production of
mini- and process computers was integrated into the automatic control
engineering division of AEG. When AEG was bought by Daimler in 1985,
"Telefunken" was dropped from the company name.
In
2005, Telefunken Sender Systeme Berlin changed its name to Transradio
SenderSysteme Berlin AG. The name "Transradio" dates back to 1918, when
Transradio was founded as a subsidiary of Telefunken. A year later, in
1919, Transradio made history by introducing duplex transmission.
Transradio has specialized in research, development and design of modern
AM, VHF/FM and DRM broadcasting systems.
In
August 2006, it acquired the Turkish company Profilo Telra, one of the
largest European manufacturers of TV-devices, with Telefunken GmbH
granting a license for the Telefunken trademark rights and producing
televisions under that name. In 2000, Toni Roger Fishman acquired The
Diamond Shaped Logo & The Telefunken Brand Name for use in North
America. The company "Telefunken USA" [2] was incorporated in early 2001
to provide restoration services and build reproductions of vintage
Telefunken microphones. In 2003, Telefunken USA won a TEC Award for
Studio Microphone Technology for their exact reproduction of the
original Ela M 250 / 251 Microphone system. Telefunken USA has since
received several TEC Awards nominations for the following microphone
systems: the Telefunken USA M12 or C12 (originally developed by AKG),
the R-F-T M16 MkII, and the AK47. The Historic Telefunken Ela M251
microphone system entered the MIX foundation's Hall of fame in 2006. In
2008, Telefunken USA won a second TEC Award for its new Ela M 260
microphone.
As
a result of a conference held in Frankfurt in May 2009, Telefunken USA
has been renamed Telefunken Elektroakustik ("Electrical Acoustics")
Division of Telefunken and awarded the exclusive rights to manufacture a
wide variety of professional audio products and vacuum tubes bearing
the Telefunken Trade Mark, in over 27 countries worldwide. Telefunken
Elektroakustik now uses the Telefunken trademark for Professional Audio
Equipment & Component Based Electronics, such as Capacitors,
Transformers, Vacuum Tubes in North America, South America, Europe, Asia
and Australia.
" It is ironic that in the years since the introduction of PAL, Telefunken – the company that invented PAL – disappeared from the market after they were bought in the 1980s by the French company Thomson – a former SECAM protagonist.
There is further irony in the fact that even as the majority of European and Asian TV viewers benefit on a daily basis from their PAL standard TV pictures, the worldwide transition from analog to digital TV spells the end of this color standard as well as many other TV transmission standards.
What we have known as PAL, SECAM, or NTSC is now increasingly known as simply digital RGB or Y, Cr, and Cb color component signals encoded in a DVB (Digital Video Broadcasting) signal or one of its many variants such as DVB-T, DVT-S, DVB-C, DVB-H, or similar ones like your ATSC.
In the future, all this may in turn disappear into an abstract IP (Internet Protocol) packet, which would make traditional distribution channels obsolete. For example, major areas in Germany, and all of Austria may terminate their analog transmissions, replacing them with DVB-T or DVB-S only.
We will find out whether the 55th anniversary of PAL in 2018 will generate much of a resonance, if all analog TV transmissions – whether terrestrial, satellite, or cable – have been brought to an end. "
TWO ARCH RIVALS. ONE INNOVATIVE COMPANY
At the beginning of the last century, two rival research groups were working in the field of
wireless telegraphy. The Slaby-Arco group was represented by the radio-telegraphy department
of AEG, founded in 1899. The other as the Braun-Siemens group, represented by a company
called Gesellschaft für drahtlose Telegraphie, System Prof. Braun und Siemens & Halske
GmbH. Under the advice of Emporer Wilhelm II, the two groups merged to form the
Gesellschaft für drahtlose Telegraphie mbH company on May 27, 1903. And the rest is history.
A TELEFUNKEN FIRST
The very first Telefunken customers were the German Army and the Imperial Navy.
Telefunken was proud to deliver the first two transmitters for the new coastal radio station, Norddeich
Radio, in November 1905. In October 1906, the expansion of a much larger Nauen station was
completed with a range of 300 km and HF output of 10 kW. Welcome to the power of
Telefunken.
MEET DR. TELEFUNKEN
Dr. Georg Graf Von Arco was the first Technical Director and Managing Director of the
Gesellschaft für drahtlose Telegraphie mbH in 1903. He was also the holder of more than one
hundred patents. Among other inventions, he initiated the high-frequency mechanical
transmitter and the wavemeter. Necessity is the mother of invention. Or in this case, German
inventions.
1923 – 1936
TELEFUNKEN GOES COMMERCIAL
On April 17, 1904, the company changed its name to "Telefunken, Gesellschaft für drahtlose
Telegraphie", and on July 26, 1932 Telefunkenplatte GmbH officially began its commercial
activity with registered capital of 100,000 Reichsmarks.
The station in the Telefunken building, Tempelhofer Ufer 9 in Berlin, began broadcasting
concerts regularly two and a half months before the official start of the "Deutsche
Rundfunkverkehr". The world tour of the Graf Zeppelin airship in 1929 got off the ground by
using Telefunken transmitters, receivers and directional equipment exclusively.
Also, on October 31, 1928, during the 5th Grand German Radio Exhibition in Berlin, Telefunken
presented a television set with the Karolus-Telefunken system, a scanning process of film
images through a Mechau projector with a Nipkow disk, in public for the first time.
MEET TELEFUNKEN’S MAD SCIENTISTS
Dr. Hans Bredow is considered to be the "Father of Broadcasting". He was employed at
Telefunken from 1904 to 1919 as a Project Manager, and later as Managing Director.
Prof. Dr. Walter Bruch developed the very first electronic television camera, with which he
participated in the live broadcast of the Olympic Summer Games in Berlin in 1936. He also
earned international fame by inventing the PAL color television system. He joined Telefunken's
Television and Physical Research Department in 1935.
These two innovators thought out of the “TV box” and helped shape and make Telefunken what
it is today.
WELCOME TO RADIO TELEFUNKEN
The German radio station in Zeesen near Königswusterhausen (8 kW shortwave transmitter) was built by Telefunken and was officially placed in service on August 28, 1929. The Mühlacker radio station (60 kW output) was handed over on December 20, 1930. Telefunken is now in, and on, the air.
TELEFUNKEN GOES FOR THE GOLD, SILVER AND BRONZE
In 1935, Telefunken equipped the Olympic Stadium, the Maifeld and the Dietrich-Eckhardt
Stage with electrical-acoustic equipment for the Olympics. On August 1, 1936 at the XI Olympic
Summer Games in Berlin, an electronic television camera, known as the Ikonoskop, was used
for the first time for a direct transmission. Again, another Telefunken first. And second. And third
1936- 1954
NOW PLAYING ON CHANNEL TELEFUNKEN
The first fully electronic television studio equipped by Telefunken for the Deutsche Reichspost
was opened with a live broadcast in August 1938. The 500 kW long wave transmitter in
Herzberg, also known as the most powerful German broadcast transmitter, was supplied by
Telefunken and began to operate on May 19, 1939.
IT’S NOT A MERGER. IT’S A POWERHOUSE
On September 24, 1941, AEG took over the 50% of Telefunken shares owned by Siemens &
Halske AG valued at 20 million Reichsmarks. Thus, Telefunken became a 100% subsidiary of
AEG. In exchange, Siemens & Halske AG received the shares of Eisenbahn-Signalwerken,
Klangfilmgesellschaft mbH and Deutsche Betriebsgesellschaft für drahtlose Telegraphie
(DEBEG) owned by AEG. Strength in numbers, indeed.
POST WWII
The reconstruction after the World War II posed a particularly difficult challenge to Telefunken.
All production facilities and equipment were destroyed, disassembled or confiscated and many
valuable experts were scattered around the world. Rebuilding began in West Germany and
Berlin in 1945, and the production of tubes and transmitters was resumed the same year. But
growth was on the way.
THE TELEFUNKEN COME BACK
In 1953 Telefunken already comprised six plants and five sales offices in Berlin, Ulm,
Frankfurt/Main and Hanover again.The range of products consisted of long-range
communications systems, radio and television transmitters, marine radios, commercial
receivers, directional and navigation systems, radar devices, deci and UHF directional radio
connections, mobile radio systems, portable radio systems, HF heat generators, measuring
equipment, electro-acoustical systems, music centers, record players, transmitter tubes, radio
tubes, special tubes and quartz crystals. As you can see, Telefunken was relentless and has
come a long way.
PROF. DR. DR. WILHELM T. RUNGE THE FIRST
Prof. Dr. Dr. Wilhelm T. Runge (1895-1987) performed trailblazing work in radio and radar
technology and played a significant role in the development of microwave in Germany. He was
especially renowned internationally in the field of high-frequency technology. As well as for
having a few, very important titles before his name.
1955 – 1962
AS TELEFUNKEN GROWS, SO DOES ITS NET WORTH
The name of the company was changed to Telefunken GmbH on January 4, 1955. Due to the
expanded business activities of Telefunken, AEG increased the capital of the company to DM
100 million in 1958.
THE FIRST GERMAN STEREO STUDIO. BROUGHT TO YOU BY TELEFUNKEN
The Sender Freies Berlin (SFB) station ordered the first German stereo studio in 1961. The
harbor radar system, supplied by Telefunken, was officially placed for service in Hamburg
Harbor in August 1962, while the first German transistor receiver (six transistors) was produced
in a test series in 1956. Prof. Dr. Walter Bruch filed the fundamental PAL "time decoder" patent
on December 31, 1962. It was the first German stereo studio of its kind, and Telefunken sought
to it that there was nothing else quite like it.
1963-1978
WHAT’S IN A NAME?
Telefunken GmbH became Telefunken AG on July 5, 1963. On June 23, 1966, the General
Shareholder Meeting of AEG passed a resolution to integrate Telefunken AG into Allgemeine
Elektrizitäts-Gesellschaft. Based on an operating lease agreement, the business activities of
Telefunken were transferred to AEG effective January 1, 1967, and were continued under the
combined name AEG-Telefunken. In March 1968, AEG-Telefunken developed a new mediumrange
radar system (Type SER-LL), which was able to detect targets at an altitude of 24,000
meters at a distance of 280 kilometers. Telefunken expands on land, as well as in the air.
TAPE RECORDERS WORTH MILLIONS
AEG-Telefunken delivered the two-millionth tape recorder, a Magnetophon 204 TS, on August
5, 1969. The ten-millionth black-and-white television picture tube was produced in Ulm on
January 27, 1970. The numbers are astounding. As is Telefunken.AEG-Telefunken delivered the
two-millionth tape recorder, a Magnetophon 204 TS, on August 5, 1969. The ten-millionth
black-and-white television picture tube was produced in Ulm on January 27, 1970. The
numbers are astounding. As is Telefunken.
ECONOMIC SLOWDOWN
There was a worldwide economic slowdown in the wake of the oil crisis in 1974. The
competition in consumer electronics sector also became more difficult due to Japanese
suppliers. The only profitable divisions of the company at this time were telecommunications
and traffic technology. But Telefunken, as usual, was known for their resilience.
1979- 1983
THE NAME GAME CONTINUES
The name of the overall company was changed to AEG-Telefunken Aktiengesellschaft on June
21, 1979. The "Aktiengesellschaft" [stock corporation] suffix was necessary due to a new law in
the European Community. In 1979, AEG-Telefunken supplied the complete telecommunications
and high-voltage equipment for the International Congress Center (ICC) Berlin, valued at DM 50
million. In January 1983 the company received an order for simulation systems for electronic
battle simulation for training Tornado crews of the German Luftwaffe and Navy. The total value
was at DM 37 million. The net worth: priceless.
TOUGH TIMES FOR TELEFUNKEN
Court composition proceedings were opened against the assets of AEG-Telefunken AG by the
District Court in Frankfurt / Main on October 31, 1982.
The District Court Frankfurt / Main confirmed the composition of AEG-Telefunken AG in
accordance with the petition filed and closed the proceedings on September 19, 1984.
Even during this difficult financial situation, AEG-Telefunken continued its business and founded
AEG-Telefunken Nachrichtentechnik GmbH (ATN), in Backnang, Germany, together with
Bosch, Mannesmann and Allianz Versicherungs-AG in 1981, as well as Telefunken electronic
GmbH (TEG) in the field of electronic components (semiconductors) together with United
Technologies Corporation (UTC), USA in 1982.
On July 1, 1992, AEG-Telefunken and Deutsche Aerospace (Dasa) founded Telefunken
Microelektronic GmbH (TEMIC), into which Telefunken Elektronic GmbH was integrated among
others. But Telefunken was determined to prevail.
A FINAL, BUT NOT LAST, TURN
Effective March 31, 1983, the French group Thomson-Brandt S.A. took over 75 percent of the
AEG-Telefunken shares in Telefunken Fernseh und Rundfunk GmbH, Hanover, Germany,
including its German and foreign subsidiaries. The remaining 25 percent were supposed to
follow on January 31, 1984. Daimler-Benz AG entered the company in autumn of 1985 and
decided in Autumn 1995 to dissolve the legal entity and transferred the remaining assets to
EHG Electroholding GmbH. Thus, the history of the company was over. But not that of its
brands.
A historical overview is offered by the company archive of AEG-Telefunken in the "Deutsches
Technikmusem Berlin", Trebbiner Str. 9, 10963 Berlin.
1984 – 2004
INNOVATION YESTERDAY. TODAY. AND TOMORROW
Currently, the Telefunken brand and name rights lie with Telefunken Licenses GmbH,
Frankfurt/Main, Germany. This company is one hundred percent subsidiary of EHG
Elektroholding GmbH, Frankfurt/Main.
EHG, on the other hand, is the legal successor of AEG Aktiengesellschaft. The licensor is
Licentia Patent-Verwaltungs GmbH, Frankfurt/Main, Germany. A differentiation is made
between brand licensing agreements, name use agreements and combined agreements. And
third-party use always requires the written approval of the licensor.
In 2003, Telefunken can look back at one-hundred years of brand history. In the past,
Telefunken was associated with significant technical developments and enjoyed the reputation
of a successful German company.
The Telefunken brand is registered in the official trademark registries of 118 countries. It
continues to be used under a variety of licensing agreements.
These are the topics that can be found in the commemorative volume "Telefunken After 100
Years - The Legacy of a Global German Brand."
Whether discovered on this website or in book, these topics should not only focus attention on
the past, but also simultaneously highlight the beginning of a strong Telefunken brand. Simply
put, it’s not just about where we’ve been. But also where we’re going.
2004 – 2009
TELEFUNKEN TODAY
Since December 2007, the trademark-right TELEFUNKEN rests with TELEFUNKEN Holding
AG, Frankfurt. Currently, TELEFUNKEN is the owner of more than 20,000 patents and active in over 130 countries around the globe.
Today, TELEFUNKEN stands for innovation and progress in the ever-changing world of
information and communications technology and is strictly focused on consumer quality – from
design concept to execution. And because of its strong heritage and long-standing tradition,
Telefunken has a high brand-awareness and a clear positioning in the field of premium
products.
Thomas Edison & GE
The year was 1876, America's centennial, and for most Americans, a time for looking backward with pride. For others like Thomas Edison it was a time to look forward to the possibilities that lay ahead. The electrical exhibits at the Centennial Exposition in Philadelphia marked the beginning of a productive new era of harnessing our imagination.1876 was also the year that Thomas Alva Edison opened a laboratory in Menlo Park, New Jersey, where he could explore the possibilities of the dynamo and other electrical devices that he had seen in the Exposition. Out of that laboratory was to come perhaps the greatest invention of the age - a successful incandescent electric lamp.
By 1890, Edison established the Edison General Electric Company by bringing his various businesses together.
During that period, a competitor emerged. The Thomson-Houston Company became a dominant electrical innovation company through a series of mergers led by Charles A. Coffin, a former shoe manufacturer from Lynn, Massachusetts.
As both businesses expanded, it had become increasingly difficult for either company to produce complete electrical installations relying solely on their own patents and technologies. In 1892, the two companies combined. They called the new organization the General Electric Company.
Several of Edison's early business offerings are still part of GE today, including lighting, transportation, industrial products, power transmission, and medical equipment. The first GE Appliances electric fans were produced at the Ft. Wayne electric works as early as the 1890s, while a full line of heating and cooking devices were developed in 1907. GE Aircraft Engines, the division's name only since 1987, actually began its story in 1917 when the U.S. government began its search for a company to develop the first airplane engine "booster" for the fledgling U.S. aviation industry. Thomas Edison's experiments with plastic filaments for light bulbs in 1893 led to the first GE Plastics department, created in 1930.
It started in a barn in 1900 when General Electric Company was only eight years old. This space housed some of the company's first breakthrough technologies and big ideas that would later ignite the world's imagination.
Charles Proteus Steinmetz, already a distinguished industrial scientist, was hard at work as GE's chief consulting engineer. After years of persuasion, Steinmetz convinced the GE leadership that the company would need a research laboratory to maintain its edge in lighting and electricity and also finding new areas to grow.
Elihu Thomson, a founder of the company, summed up the mission of the lab: "It does seem to me therefore that a Company as large as the General Electric Company, should not fail to continue investing and developing in new fields: there should, in fact, be a research laboratory for commercial applications of new principles, and even for the discovery of those principles."
Charles Coffin, GE's first CEO, agreed and the GE Research Laboratory was born in the carriage barn in Steinmetz's back yard. Willis Whitney, a young chemistry professor from MIT who had been conducting experiments for GE, was invited to become the first director.
One of the earliest projects of the new lab was to defend the company's primary asset — incandescent lighting — through innovation. In 1908, GE scientist William Coolidge invented the ductile tungsten filament that made the GE incandescent lamp significantly more durable than the original design. The invention secured GE's technological leadership in the market and epitomized the role of the GE research lab — bringing innovation to the marketplace.
Over the years, the research lab has brought many new technologies to GE's customers. Along the way, GE scientists have amassed thousands of patents, and two Nobel prizes: Irving Langmuir won the Nobel prize in Chemistry in 1932 and Ivar Giaever won the Nobel Prize in Physics in 1973.
Today, GE Global Research consists of more than 3,000 employees working in four state-of-the-art facilities: Niskayuna, New York (a few miles from the original barn), Bangalore, India (opened in September 2000), Shanghai, China (opened in October, 2003), and Munich, Germany (opened in June, 2004).
While Steinmetz and Whitney might not recognize the facilities today, they would feel very comfortable with the lab’s mission — spurring GE's growth by bringing innovative technology to the world.
A good point on good old B/W Televisions.....................
The Sixties was a time of great change for TV. At the start of the decade there were just monochrome sets with valves, designed for 405 -line transmissions at VHF. By the end there was 625 -line colour at UHF, with transistorised chassis that used the odd IC.
The following decade was one of growth. The "space race" had begun in 1957, when the USSR launched Sputnik 1 and terrified the Americans. Thereafter the USA began to spend countless billions of dollars on space missions. This got underway in earnest in the Sixties, with the announcement that America would be going all out to get a man on the moon by the end of the decade. There followed the Mercury series of earth - orbit missions, then the Apollo launches. Success was achieved in 1969. Most of these missions were televised, and in those days anything to do with space was hot stuff. It was inevitable that everyone wanted to have a television set. At the time an average receiver would be a monochrome one with a 14in. tube - there was no colour until 1967. It would cost about 75 guineas.
TV sets were often priced in guineas (21 shillings) as it made the price look a bit easier on the pocket. Anyway 75 guineas, equivalent to about £78.75 in 2000's currency, was a lot of money then. For those who couldn't, rental was a good option. The Sixties was a period of tremendous growth for rental TV.
Much else was rented at that time, even radios, also washing machines, spin driers, refrigerators and, later on, audio tape recorders (no VCRs then).
For most people these things were too expensive for cash purchase.
There were no credit cards then. And when it came to a TV set, the question of reli- ability had to be taken into account: renting took care of repair costs.
TV reliability.........The TV sets of the period were notoriously unreliable. They still used valves, which meant that a large amount of heat was generated. The dropper resistor contributed to this: it was used mainly as a series device to reduce the mains voltage to the level required to power the valve heaters. These were generally connected in series, so the heater volt- ages of all the valves were added together and the total was subtracted from the mains voltage. The difference was the voltage across the heater section of the dropper resistor, whose value was determined by simple application of Ohm's Law.
As valves are voltage -operated devices, there was no need to stabilise the current. So the power supply circuits in TV sets were very simple. They often consisted of nothing more than a dropper resistor, a half or biphase rectifier and a couple of smoothing capacitors. If a TV set had a transformer and a full wave rectifier in addition to the other components, it was sophisticated!
As the valve heaters were connected in series they were like Christmas -tree lights: should one fail they all went out and the TV set ceased to function. Another common problem with valves is the cathode -to -heater short. When this fault occurs in a valve, some of the heaters in the chain would go out and some would stay on. Those that stayed on would glow like search- lights, often becoming damaged as a result. Dropper failure could cause loss of HT (dead set with the heaters glowing), or no heater supply with HT present. When the HT rectifier valve went low emission, there was low EHT, a small picture and poor performance all round. CRTs would go soft or low emission, the result being a faint picture, or cathode -to -heater short-circuit, the result this time being uncontrollable brightness. On average a TV set would have twelve to fourteen valves, any one of which could go low -emission or fail in some other way. All valves have a finite life, so each one would probably have to be replaced at one time or another. The amount of heat generated in an average TV set would dry out the capacitors, which then failed. So you can see why people rented!
The CRT could cause various problems. Because of its cost, it was the gen- eral practice to place its heater at the earthy end of the chain. In this position it was less likely to be overloaded by a heater chain fault. But during the winter months, when the mains voltage dropped a bit, it would be starved of power. This would eventually lead to 'cathode poi- soning' with loss of emission. The 'cure' for this was to fit a booster transformer designed to overrun the heater by 10, 20 or 30 per cent. It would work fine for a while, until the CRT completely expired. At about this time CRT reactivators came into being - and a weird and wonderful collection of devices they turned out to be. Regunned tubes also started to appear. You couldn't do this with the `hard -glass' triode tubes made by Emitron. These were fitted in a number of older sets. Yes, they were still around, at least during the early Sixties.
Developments................... A great deal of development occurred during the Sixties. Many TV sets and radios made in the early Sixties were still hard -wired: the introduction of the printed circuit board changed the construction of electronic equipment forever. The first one was in a Pam transistor radio. PCBs were ideal for use in transistor radios, because of the small size of the components used and the fact that such radios ran almost cold.
They were not so good for use with valve circuitry, as the heat from the valves caused all sorts of problems. Print cracks could develop if a board became warped. If it became carbonised there could be serious leakage and tracking problems. In addition it was more difficult to remove components from a PCB. Many technicians at that time didn't like PCBs. As the Sixties progressed, transistors took over more and more in TV sets. They first appeared in a rather random fashion, for example in the sync separator stages in some Pye models. Then the IF strip became transistorised. Early transistors were based on the use of germanium, which was far from ideal.
The change to silicon produced devices that were more robust and had a better signal-to-noise ratio.
Car radios became fully transistorised, and 'solid-state' circuitry ceased to be based on earlier valve arrangements. Many hi-fi amplifiers had been transistorised from the late Fifties, and all tape recorders were now solid-state.
Both reel-to-reel and compact -cassette recorders were available at this time. Initially, audio cassette recorders had a maximum upper frequency response of only about 9kHz.
To increase it meant either a smaller head gap or a faster speed. Philips, which developed the compact audio cassette and holds the patents for the design (which we still use in 2000!) wouldn't allow an increase in speed. Good reel-to-reel recorders had a fre- quency response that extended to 20kHz when the tape speed was 15in./sec.
This is true hi-fi. In time the frequency response of compact -cassette recorders did improve, because of the use of better head materials with a smaller gap.
This led to the demise of the reel-to-reel audio recorder as a domestic product We began to benefit from spin-offs of the space race between the USA and the USSR.
The need to squeeze as much technology as possible into the early computers in the Mercury space capsules used by the USA lead to the first inte- grated circuits.
This technology soon found its way into consumer equipment. Often these devices were hybrid encap- sulations rather than true chips, but they did improve reliability and saved space. The few chips around in those days were analogue devices. To start with most UHF tuners used valves such as the PC86 and PC88. They were all manually tuned. Some had slow-motion drives and others had push -buttons. They didn't have a lot of gain, so it was important to have an adequate aerial and use low -loss cable..............................
The B/W Tubes Television set was powered with a External Voltage stabiliser unit (portable metal box) which relates to voltage regulators of the type employed to supply alternating current and a constant voltage to a load circuit from a source in which the line voltage varies.Conventional AC-operated television receivers exhibit several undesirable performance attributes. For example, under low-line voltage conditions such as those encountered during peak load periods or temporary power brown-outs imposed during times of power shortage, picture shrinkage and defocusing are encountered and under extreme brown-out conditions the receiver loses synchronization with a resultant total loss of picture intelligibility.
On the other hand, abnormally high-line voltage conditions are sometimes encountered, and this can lead to excessive high voltage and X-ray generation. In addition, either abnormally high steady state line voltage conditions or high voltage transients such as those encountered during electrical storms or during power line switching operations may subject the active devices and other components of the receiver to over-voltage stresses which can lead to excessive component failure.
It is a principal object of the present invention to provide a new and improved AC-operated television receiver having greatly improved performance characteristics in the presence of fluctuating power supply voltages.
A more specific object of the invention is to provide an AC-operated television receiver affording substantially undegraded performance under even extremely low-line voltage conditions without excessive high voltage and X-ray generation under even extremely high-line voltage conditions.
Still another and extremely important object of the invention is to provide a new and improved AC-operated television receiver having greatly improved reliability against component failure. Such regulators are frequently provided employing saturable core reactors and condensers connected in circuit... in such manner as to provide a plurality of variable voltage vectors which vary in different senses, as the line voltage varies, but which add vectorially in such manner that their vector sum remains substantially constant upon variations in line voltage, for providing automatic voltage stabilization of single or multiphase A. C. circuits where the supply voltage and frequency are subject to variation above and below normal value and where the load is subject to variation between normal limits.
voltage stabilization
is automatically effected by the provision of an inductive pilot control device which is adapted to provide two excitation supply voltages for producing excitation or satuation of two magnetic circuits of a reversible booster transformer unit or units and diversion of flux from one magnetic circuit to the other, the booster unit being energized by primary windings from the A. C. supplysystem and being provided with a secondary winding or windings connected between the supply system and the corresponding inain or distribution circuit and in series therewith, through which a corrective boost voltage is
imrorjiiced into the circuit under the influence of the pilot control device, of an amount equal to that of the supply voltage fluctuation which initiated it and appropriate in polarity and direction for restoring the voltage to normal value and providing automatic stabilization of the circuit voltage against supply voltages which fluctuate above and below normal value.
The pilot control device which may be employed singly or may comprise three units or their equivalent when applied to multiphase supply systems comprises a pair of closed magnetic circuits or cores constructed of strip wound magnetic material or stacked laminations, the two
circuits forming a pair being constructed of materials possessing dis~similar magnetic characteristics when jointly energized by identical windings in series or by a collective primary winding, the said magnetic circuits being suitably proportioned to provide equal fluxes when ener-
gized at normal voltage.
The pilot control device is provided with a main and an auxiliary secondary winding or group of windings, the main secondary winding or windings being adapted to provide a voltage representing the difference in the fluxes of the two circuits to which it is jointly associated, while
the auxiliary secondary winding embraces only one circuit, preferably that subject to the least amount of flux variation. Either of the windings consists of two equal sections or in effect a double winding with a center tapping to which one end of the single winding is connected.
The voltage in the single secondary winding of the pilot device becomes directionally additive to that in one half of the tapped secondary winding and substractive in respect to that in the other half. When the supply voltage is normal the voltage provided by the single secondary winding is zero, since there is no difference of flux in the two magnetic circuits, and the two excitation voltages
produced in the halves of the other secondary winding are equal and when connected to the two excitation windings of the booster units, do not produce any diversion of flux between the two circuits or sets of circuits in the magnetic system of the booster transformer unit become equal, and since the series winding on the booster unit is arranged to provide a voltage due to the difference of
the fluxes in its two magnetic circuits or sets of magnetic circuits, no corrective voltage is introduced into the main circuit by the booster. If, however, the supply voltage varies from normal the pilot control device provides a voltage across the one secondary winding due to the difference in the fluxes of the two dis-similar magnetic circuits of which it is comprised, which voltage is combined with thosc in the halves of the other secondary winding to provide two excitation voltages which vary complementarily to each other as the supply voltage fluotuates, and cause a transference of flux between the two
circuits or groups of circuits in the booster unit and automatically provide a corrective boost voltage in the main circuit in which the series winding of the booster transformer is includcd of a value equal to that of the variation in supply voltage which initiated it.
The pilot device may be arranged in various ways, forboth single phase and multiphase operation, as exemplified by the constructions hereinafter more fully described.Similarly, numerous arrangements of the booster transformer unit are possible, some of which are hereinafter described in detail. The booster transformer unit embodies thc principles of the inductive devices described in my co-pending Application No. 411,189, filed February 18, 1954.
As an alternative to the provision of an auxiliary secondary winding on the pilot control device this may be
replaced by an independent or external source of supply,which may be either subject to or independent of supply voltage variation, provided such supply may be arranged with a center tapping if required.
Feed-back arrangements may be employed for providing compensation against voltage drop due to the effects of load in various ways. These are preferably providedon the booster transformer unit and may comprise a current transformer in one or more lines of the main circuit,
the secondary output of the transformer being rectified and arranged to energize an additional excitation winding on the booster transformer unit which in clfect increases the amount of the corrective boost voltage as the load increases.
Some References:
- M. Friedewald: Telefunken und der deutsche Schiffsfunk 1903–1914. In: Zeitschrift für Unternehmensgeschichte 46. Nr. 1, 2001, S. 27–57
- M. Fuchs: Georg von Arco (1869–1940) – Ingenieur, Pazifist, Technischer Direktor von Telefunken. Eine Erfinderbiographie. Verlag für Geschichte der Naturwissenschaften und der Technik, Berlin & München: Diepholz 2003
- L. U. Scholl: Marconi versus Telefunken: Drahtlose Telegraphie und ihre Bedeutung für die Schiffahrt. In: G. Bayerl, W. Weber (ed.): Sozialgeschichte der Technik. Ulrich Troitzsche zum 60. Geburtstag. Waxmann, Münster 1997 (Cottbuser Studien zur Geschichte von Technik, Arbeit und Umwelt, 7)
- Telefunken Sendertechnik GmbH: 90 Jahre Telefunken. Berlin 1993
- Erdmann Thiele (ed.): Telefunken nach 100 Jahren – Das Erbe einer deutschen Weltmarke. Nicolaische Verlagsbuchhandlung, Berlin 2003, ISBN 3-87584-961-2
Einzelnachweise:
Schreibweise mit c siehe: - AEG-Teilschuldverschreibung von 1962Marke „Telefunken“ in der Registerauskunft des Deutschen Patent- und Markenamtes (DPMA)
E. Thiele (Hrsg.): Telefunken nach 100 Jahren: Das Erbe einer deutschen Weltmarke. Nicolai, Berlin 2003, S. 19
Kurt Kracheel: Flugführungssysteme (Die Deutsche Luftfahrt, Band 20). Bernard&Graefe Verlag, Bonn 1993, ISBN 3-7637-6105-5, S. 119.
Operette 50W UKW. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Autosuper IA 50. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Farbfernseh-Tischempfänger PALcolor 708T. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Mini Partner 101. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Olympia-Partner. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Magnetophon 3000 hifi. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Fernseh-Tischempfänger FE8T. In: radiomuseum.org. Abgerufen am 28. Januar 2016.
Israelischer Konzern Elbit Systems eröffnet Büro in Berlin. In: bundeswehr-journal. 13. April 2018, abgerufen am 18. Januar 2019.
Telefunken Semiconductors Heilbronn: Die Lichter sind für immer aus, swr.de, 27. Februar 2015
LDL Berlin: Geschäftshaus Mehringdamm 32 & 34
LDL Berlin: AEG-Glühlampenfabrik
LDL Berlin: AEG-Telefunken-Gerätewerk
Telefunkenwerk Celle. vergessene-orte.blogspot.com
Ludwig Leisentritt: Die historische Entwicklung von Zeil am Main, hbrech.tripod.com
No comments:
Post a Comment
The most important thing to remember about the Comment Rules is this:
The determination of whether any comment is in compliance is at the sole discretion of this blog’s owner.
Comments on this blog may be blocked or deleted at any time.
Fair people are getting fair reply. Spam and useless crap and filthy comments / scrapers / observations goes all directly to My Private HELL without even appearing in public !!!
The fact that a comment is permitted in no way constitutes an endorsement of any view expressed, fact alleged, or link provided in that comment by the administrator of this site.
This means that there may be a delay between the submission and the eventual appearance of your comment.
Requiring blog comments to obey well-defined rules does not infringe on the free speech of commenters.
Resisting the tide of post-modernity may be difficult, but I will attempt it anyway.
Your choice.........Live or DIE.
That indeed is where your liberty lies.
Note: Only a member of this blog may post a comment.