词条 | Pirna 014 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
释义 |
The Pirna 014 was an axial turbojet designed in East Germany (or the GDR) in the mid- to late 1950s by former Junkers engineers, who were repatriated to East Germany in 1954 after being held in custody in the Soviet Union following World War II.[1] OriginAfter the remaining groups of German aircraft technology engineers, those which were not yet about to be repatriated back home, had been concentrated in Sawjelowo north of Moscow in December 1953, development planning for a four jet engine-powered civilian airliner started. The role of head of engine research & development was assigned to (then Dipl.-Ing.) Ferdinand Brandner, whereas (then Dipl.-Ing.) Brunolf Baade was given the general project lead. Before Brandner finally went back to his family in Austria, after being forced to stay in the Soviet Union for 9 years, he selected his deputy (then Dr.-Ing.) Rudolf Scheinost to continue his work and to lead development of the engine. The engine project 014, a continuation of the numbering sequence of previous Jumo jet engines, was at this time named Dwigatel 014 (from reactivnyi dvigatel, literally "jet drive") and given high priority. As for the airliner that was intended being powered by project 014, it was the Baade 152 passenger jet, which was to be developed and constructed as pre-production aircraft at VEB Industriewerke Dresden (Factory 803),[2] part of which was the later VEB Flugzeugwerke Dresden. On 5 July 1954 the last group of 200, mainly engineers but finally also the key technical leads and minds, arrived in the Saxon town of Pirna. While only some persons, for example Ferdinand Brandner or Günther Bock left again shortly afterwards for their final destinations in Austria and West Berlin, the majority were eager to continue with engine and aircraft development in the GDR. In a part of the town called Sonnenstein (literally sun stone, which itself is situated on a plateau between the river valleys of Elbe in the North and Gottleuba in the West), work centered around planning of future operations / building factories and related to 152 and 014 started almost instantly. First they operated from the buildings of HV-18 (Hauptverwaltung 18, which was established earlier, in 1951/1952), until construction work for the engine development works started in the summer of 1955. A new design and administration building, almost identical to the one in Dresden located at Factory 801, was constructed. Two large assembly and manufacturing plants, several engine test stands (with their characteristic towers), large underground tanks intended for test runs, other halls and social facilities, plus housing for the workers were finished. VEB Entwicklungsbau Pirna (Factory 802) (renamed VEB Gasturbinenbau und Energiemaschinenentwicklung Pirna in 1961, later in 1970 transformed into VEB Strömungsmaschinen Pirna) was officially founded there on 1 May 1955. (Other development works and factories that later formed the East German aviation industry were founded on the same date. See History of East German aviation industry.) The project documentation that was already begun before final return of the engineers involved to Germany, was extended by a new, enlarged team now being located in Pirna and prepared for prototyping. From the beginnings in 1954 until the completion of new factories in 1957, the premises in Pirna were basically operating as the spiritual center of aviation-related research, development & production in the GDR. Only from thereon, it was that upper management level moved to their new offices in Dresden. Design and developmentDesignCitations: Mewes 1997, p. 36-39.It was designed as a single-shaft, single-flow turbojet. The basic conception was a further development of the design already applied with high perfection on Junkers Jumo 004 and Junkers Jumo 012, as well as the BMW 003 and BMW 018 engines. In this design, the compressor, combustion chamber and turbine are traversed in axial direction by the air taken directly from the inlet. The experiences acquired by technical management in the Soviet Union during further development of mentioned Junkers and BMW engines, as well as entirely new developments like TW-2, NK-2 / NK-4 (Soviet program names of Jumo 022 developments, leading to TV-022 and 2TV-2F engines) along with the high-power turboprop NK-12 were considered during design and construction of components for this new engine project. This knowledge was now serving as a foundation for the enlarged Pirna team to develop a modern, simple and robust jet engine from the already existing project documentation, which would be suitable for a civilian airliner according to specific needs regarding power requirements, simple handling, reliability, and low maintenance.
The twelve-stage axial compressor was coupled directly to the two-stage turbine, just like on the Jumo 012. This resulted in relatively simple bearings construction and advantageous controllability. The compressor housing was a welded steel sheet construction, divided in two parts. The upper half contained the fuel- and engine control systems, later also the automated starter control and ignition coils for two ignitors located in the combustion chamber's upper area.
Engine control was handled by a fully automatic, compact commando unit using a proven Junkers single-handed lever action. In various states of flight, fuel throughput can vary greatly. Therefore, fuel injectors located in the burners were given two stages, resulting in good efficiency over a large operational range.
The chamber was a can-annular design. Based on experiences with Junkers' can-type chambers (Jumo 004) and BMW's annular-type chambers (BMW 003), this design choice was successfully applied already during the Soviet period. 12 burner cans and 60 air pockets (integrated into inner and outer wall) were used, along with several more air canals. This construction proved an efficiency of about 98% burn-out grade inside the combustion chamber during bench-tests. This construction achieved an all-around flow of cooling air of chamber walls, so those were relatively protected of the high temperatures inside the chamber, which reached up to 3200 °C in the flame area. Thus, thermal requirements for chamber wall and air pocket materials were determined to be considerable lower at first. Engine inlet temperature was calculated to be around 780 °C (1050°K), as higher-temperature resistant materials were not available at this time.
For the two-stage reaction turbine, a low cooling effect for the turbine discs was achieved using a skillful airflow, which was diverted from beneath the combustion chamber and directed inwards toward the shaft. The turbine blades were not cooled, but the guide blades for the first turbine stage were fabricated hollow. The major part of exhaust gases' thermal gradient was distributed equally on both turbine stages; the remainder converted to a thrust of 3150kp, using a fixed thrust nozzle.
The assembly of both components has changed; they were not anymore attached using a separate equipment carrier behind the engine. Integrated into a single component and inserted into the intake bullet, it worked directly on the shaft, where it was coupled with the engine-rotor using a separate transmission assembly for the starter.
Originally to be mounted beneath the engine, it was re-designed as an annular oil tank. The new mounting place was now in the diffuser area, in front of the air-intake casting.
This component was made from light metal cast design. Using a separator transmission coupled to the compressor rotor, the upper-mounted equipment carrier for fuel pump & control-pressure transmitter as well as the oil pump block were driven.
Initially, 4 rectangular blow-off flaps (valves) were installed; later they were changed to 8 round flaps. Further during the re-design process, specifically from prototype engine V-07 onwards, this implementation was changed to a different, better controllable system which involved an annular blow-off belt. Revision A0Citations: Mewes 1997, p. 39-42.A mock-up engine designated V-00 was used for testing assembly & positions of components, pipes and fittings. Positions of electrical / pipe connections were also determined & matched after coordinations done with the people responsible for airframe construction in Klotzsche. In parallel, a first trial engine was constructed at VEB Entwicklungsbau Pirna. This was engine V-01, which only at this time adopted the final program designation "Pirna 014" that was derived from both town name and former designation. It took two years of construction- and assembly time; so in October 1956 a first trial was made possible. Revision A1Citations: Mewes 1997, p. 47-49.Introduced changes for revision A-1 were:
During compressor trials it was discovered that the compressor's operational range was too narrow for cruising altitudes greater than 5000m. Therefore, the compressor of revision A-0 which was conceived already in the Soviet Union had to be redesigned. Those changes related to compressor blades and the blow-off system resulted in a quieter, smoother rotor behavior, as well as better pump characteristics. Associated critical revolutions were now in a range better suited for flight, resulting in a broader compressor operational range. Air consumption was increased by 5,5 kg/s (52.0 kg/s to 57.5 kg/s), resulting in a thrust increase from {{convert|30.89|kN}} to {{convert|32.36|kN}}. With this revision, the intake de-icing using an integrated de-icing system was proven in the winter months of 1960. Also, bird strike trials did not disturb engine operation. (See Special trials section.) TrialsBench trialsEngine V-01 was first run on 12 October 1956 on engine test stand 2 in building complex 62 under reduced load for about 2.5h.[3] Pushing the engine under full load was not possible at this time, the reason being the use of non-heat-resistant materials as those were not available domestically. The original intention was to just perform aerodynamic measurements proving correct engine test stand functionality, as well as to test oil circulation on a completed engine. Yet, the decision was made to let the engine freely run on its own power. After five start attempts, ignition was achieved, the jet carefully reaching 6200rpm. No disruptions were recorded. First accident happened on 25 February 1958. During V-01 measurement run 50 on engine test stand 1, turbine stage 2 failed, which led to partial destruction of the engine from the combustion chamber onwards. (Mewes 1997, p. 42.) All prototype engines from V-02 to V-14 were essentially used for experimental and measurements runs. Such trials as well as endurance tests were needed to secure engine airworthiness certification. After five years of research and development, in the second half of 1959 type certification was achieved after engine V-017 successfully completed a 150-hour endurance trial. Thus, an important prerequisite for beginning of flight trials was met. Flight trialsThe first flight trial was then performed on 11 September 1959, using an Ilyushin Il-28R with the engine mounted on the underside of the fuselage. Four A-0 engines were used in the second Baade 152 prototype 152/II V4. Special trials{{Empty section|date=August 2012|section=}}Production{{Empty section|date=August 2012|section=}}End of Program{{Disputed-section|date=August 2012}}Because of political decisions, which were associated with Soviet interests, the Baade 152 program and all other aircraft programs in development at VEB Flugzeugwerke Dresden, which at the time was the entire aircraft industry of the GDR, were stopped in 1961. Except for minor remnants, the aircraft industry in the GDR was then dissolved. The Pirna 014 engines that were already series-produced (revisions A0 and A1) at VEB Industriewerke Ludwigsfelde (Factory 807)[4] were put to other uses, including as emergency power generators. Applications
Variants
Further developments
Variants table
Specifications (Pirna 014-A0){{jetspecs|ref=Mewes, Pirna 014. Flugtriebwerke der DDR. |type=Turbojet |length={{convert|3446|mm|abbr=on}} |diameter={{convert|981|mm|abbr=on}} |weight={{convert|1060|kg|abbr=on}} |compressor=twelve-stage axial-flow |combustion=can-annular combustion chamber, 12 cans |turbine=two-stage |fueltype=kerosene / jet fuel (specification T-1) |oilsystem= |power= |thrust={{convert|3150|kp}} at 8000rpm, non-afterburning |compression=7:1 |bypass= |aircon=52.0kg/s |turbinetemp=1050°K |fuelcon= |specfuelcon=0.85kg/kph |power/weight= |thrust/weight= }} List of engines producedPrototypes table (Factory 802)Pirna 014
Series production table (Factory 807)
SurvivorsSurvivors known to exist:
See also{{aircontent|see also= |related=
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References
1. ^"Das Triebwerk-Entwicklungswerk Pirna (Werk 802)," www.flugzeug-lorenz.de Retrieved: 26 July 2012. 2. ^"Das Flugzeug-Serienwerk 803," www.flugzeug-lorenz.de Retrieved: 27 July 2012. 3. ^"Das Triebwerk-Entwicklungswerk Pirna (Werk 802)," www.flugzeug-lorenz.de Retrieved: 26 July 2012. 4. ^"Aus der DDR-Luftfahrtindustrie," www.gerdspriess.de Retrieved: 26 July 2012. 5. ^"Gasturbine Pirna 014," www.parow-info.de Retrieved: 21 July 2012. 6. ^"Turbostrahltriebwerk Pirna 014," www.saechsisches-industriemuseum.de Retrieved: 2 August 2012. 7. ^"Kaufvertrag zum Speisehaus unterzeichnet," www.pirna.de Retrieved: 2 August 2012. External links{{Commons category}}
2 : Turbojet engines 1950–1959|Junkers aircraft engines |
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