Jump to content

Micropup

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by YTRK (talk | contribs) at 05:54, 29 March 2020 (link fix). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

In electronics, a micropup is a style of triode vacuum tube (valve) developed during World War II for use at very high frequencies such as those used in radar. They are characterized by an external anode block, which allows better heat dissipation. These tubes could deliver radio frequency power on the order of kilowatts at wavelengths as short as 25 cm.,[1] and on the order of 100 kW at 200 MHz in pulses. Micropup tubes used very high voltages to minimize the transit time of electrons between anode and cathode.[2]

The micropup vacuum tube was made possible by the development of vacuum-tight joining of copper to glass, around 1939. The designs used a cylindrical anode and a concentric cylindrical grid electrode; the cathode was directly heated thoriated tungsten wires, which after the first types were all oxide coated to improve electron emission. One type, the NT99 developed by GEC could produce up to 200 kW peak output (for a pair of tubes) when used in 600 MHz radar sets. A 50 cm radar set using micropup triodes was used by HMS Suffolk to track movements of the Bismarck. [3]

Although widely used in "metre-band" radar systems, the cavity magnetron was able to produce significant power at much higher frequencies, as radar systems developed during the war.[4]

References

  1. ^ http://www.ase-museoedelpro.org/Museo_Edelpro/Catalogo/tubes/Family_descr_doc/coll_P5.pdf
  2. ^ United States Department of the Army Generation and Transmission of Microwave Energy, Technical Manual TM 11-673, June 1953, pp. 114–116
  3. ^ L. Brown, Technical and Military Imperatives: A Radar History of World War 2, CRC Press, 1999, ISBN 1420050664, page 329
  4. ^ F.A. Kingsley (ed.), The Development of Radar Equipments for the Royal Navy, 1935–45 Springer, 2016, ISBN 1349134570, pages 110–111