Jump to content

Heinkel HeS 3: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
Hoeksas (talk | contribs)
mNo edit summary
 
(65 intermediate revisions by 41 users not shown)
Line 1: Line 1:
{|{{Infobox aircraft begin
[[file:HeS 3 Turbojet.jpg|thumb|Heinkel HeS 3 Turbojet engine, at [[Deutsches Museum]].]]
|name = HeS 3
The '''HeS 3''' was the world's first operational [[jet engine]] to power an aircraft. Designed by [[Hans von Ohain]] while working at [[Heinkel]], the engine first flew as the primary power of the [[Heinkel He 178]], piloted by [[Erich Warsitz]] on August 27, 1939. Although successful, the engine had too little thrust to be really useful, and work started on the more powerful [[Heinkel HeS 8]] as their first production design.
|image = File:HeS 3 Turbojet.jpg
|caption = A sectioned Heinkel HeS 3 Turbojet engine at the [[Deutsches Museum]]
}}
{{Infobox aircraft engine
|type=Centrifugal flow turbojet engine
|manufacturer=[[Hirth|Heinkel-Hirth Motorenwerke]]
|national origin=[[Germany]]
|first run=1939
|major applications= [[Heinkel He 178]]
|number built =
|developed from =[[Heinkel HeS 1]]
|variants with their own articles =
|developed into =
}}
|}


The '''Heinkel HeS 3''' (HeS - ''Heinkel Strahltriebwerke'') was the world's first operational [[jet engine]] to power an aircraft. Designed by [[Hans von Ohain]] while working at [[Heinkel]], the engine first flew as the primary power of the [[Heinkel He 178]], piloted by [[Erich Warsitz]] on 27 August 1939. Although successful, the engine had too little thrust to be really useful, and work started on the more powerful [[Heinkel HeS 8]] as their first production design.
In some ways the HeS 3 design was simply a cleanup of the original [[Heinkel HeS 1|HeS 1]], converted to burn liquid fuel instead of the HeS 1's hydrogen gas. von Ohain was also unhappy with the large external diameter of the HeS 1, and re-arranged the layout of the new engine to allow the parts to be "folded together" in a more compact layout.


==Development==
The first HeS 3 design was generally similar to the HeS 1, using a 16-bladed [[centrifugal compressor]] supported by an 8-blade impeller to smooth out the airflow in the intake. The compressed air flowed into an annular combustion chamber arranged to lie between the compressor and turbine, which were separated much more than in the HeS 1 to allow this arrangement. The first example was bench tested around March 1938, but the arrangement led to a smaller than useful compressor and poor combustion.
The HeS 3 design was largely based on the [[Heinkel HeS 1|HeS 1]] but converted to burn liquid fuel instead of hydrogen gas used in the HeS 1. The first HeS 3 design was generally similar to the HeS 1, using an 8-blade inducer and 16-blade [[centrifugal compressor]]. The compressed air flowed into an annular combustion chamber between the compressor and turbine, which made the engine longer.{{Citation needed|date=June 2014}} The first example was bench tested around March 1938, but did not reach the design thrust because a small compressor and combustor had been used to reduce the frontal area.<ref name=Homji>"Pioneering Turbojet Developments of Dr. Hans Von Ohain-From the HeS 1 to the HeS 011" Meher-Homji and Prisell, Transactions of the ASME, Vol. 122, April 2000</ref> Max Hahn, from Heinkel, applied May 31, 1939, for a US patent, granted Sept 16, 1941: 'Aircraft Power Plant', US2256198, with the von Ohain design.


A redesign started as the HeS 3b, which dispensed with the "folded" arrangement and returned to simpler [[flame can]]s for combustion. In order to keep the dimensions small, the widest part of the cans were arranged in ''front'' of the engine, the compressed air first flowing forward into the cans, and then rearward to the tubine. Although not as compact as the original design, the 3b was much simpler. Designed to run on gasoline, the fuel flow was preheated by running it over the rear roller bearing.
An improved engine, the HeS 3b, had a 14-blade inducer and 16 blade [[centrifugal compressor]]. In order to minimise the diameter the widest part of the annular combustor was placed in line with the smaller diameter axial entry to the impeller. At exit from the impeller the air flowed forwards, then turned through 180 degrees to flow rearward through the combustor. The flow was then turned radially inwards to enter the turbine. Although not as compact as the original design, the 3b was much simpler. The fuel was used to cool rear roller bearing, which also preheated the fuel.<ref name="C.Rodgers">"A Performance Diagnosis of the 1939 Heinkel HE S3B Turbojet" C. Rodgers, GT2004-53014</ref>


The engine was completed in early 1939, and was flight-tested under one of the remaining [[Heinkel He 118]] [[dive bomber]] prototypes. The flight tests were carried out in extreme secrecy, taking off and landing under propeller power, and only flying in the early morning before other workers had arrived. Testing proceeded smoothly, but the engine eventually burned out its turbine.
The engine was completed in early 1939, and was flight-tested under one of the remaining [[Heinkel He 118]] [[dive bomber]] prototypes. The flight tests were carried out in extreme secrecy, taking off and landing under propeller power, and only flying in the early morning before other workers had arrived. Testing proceeded smoothly, but the engine eventually burned out its turbine.
Line 14: Line 30:
Hans Mauch later told von Ohain the RLM was in fact extremely impressed, but he was concerned that Heinkel's airframe team did not have the knowledge to undertake engine development. Instead he and [[Helmut Schelp]] secretly visited a number of [[aircraft engine]] manufacturers to try to start programs there. Mauch left his position in 1939 leaving Schelp in command. Schelp was not as concerned about where development was taking place, and immediately started funding Heinkel to produce a more powerful engine.
Hans Mauch later told von Ohain the RLM was in fact extremely impressed, but he was concerned that Heinkel's airframe team did not have the knowledge to undertake engine development. Instead he and [[Helmut Schelp]] secretly visited a number of [[aircraft engine]] manufacturers to try to start programs there. Mauch left his position in 1939 leaving Schelp in command. Schelp was not as concerned about where development was taking place, and immediately started funding Heinkel to produce a more powerful engine.


===HeS 6===
Work on a larger version, the '''HeS 6''', started immediately, and was tested under a [[Heinkel He 111]] late in 1939. While successful, notably in terms of vastly improved fuel economy, the weight was considered excessive and the design was abandoned in favour of the more advanced [[Heinkel HeS 8]].


Work on a larger version, the '''HeS 6''', started immediately, and was tested under a [[Heinkel He 111]] late in 1939. While successful, raising thrust just above {{convert|590|kp|lbf|abbr=on}}, weight increased from 360 to 420&nbsp;kg. The diameter of the engines remained too large to directly substitute the planned HeS 30 (109-006) engines on the He 280 fighter, therefore the design was abandoned in favour of the more compact [[Heinkel HeS 8]] utilizing a straight-through flow combustion layout.
==Specifications==


For HeS 3b:
==Specifications (HeS 3b)==
{{jetspecs
:Dimensions: 1.48 m long, 0.93 m diameter
<!-- If you do not understand how to use this template, please ask at [[Wikipedia talk:WikiProject Aircraft]] -->
:Weight: 360 [[kilogram|kg]]
<!-- Please include units where appropriate (main comes first, alt in parentheses). If data are missing, leave the parameter blank (do not delete it). For additional lines, end your alt units with )</li> and start a new, fully-formatted line with <li> -->
:Thrust: 450 [[kilogram-force|kgf]] (4.4 [[kilonewton|kN]]) @ 13,000 rpm and 800 km/h
|ref= <ref name=Kaythd>Kay 2007, pp. 171–174</ref>
:[[Compression ratio]]: 2.8:1
|type=Centrifugal flow turbojet engine
:[[Specific fuel consumption]]: 2.16 gal/(lb·h) [18.0 L/(kg·h)]
|length= {{convert|1480|mm|in|abbr=on}}

|diameter= {{convert|930|mm|in|abbr=on}}
For HeS 6:
|weight= {{convert|360|kg|lb|abbr=on}}
:Weight: 420 kg
|compressor=14-blade axial inducer + 16-blade centrifugal flow compressor<ref name="C.Rodgers"/>
:Thrust: 550 kgf (5.4 kN) @ 13,300 rpm and 800 km/h
|combustion=Reverse-flow annular<ref name="C.Rodgers"/>
:[[Specific fuel consumption]]: 1.6 gal/(lb·h) [13.4 L/(kg·h)]
|turbine=12-blade radial inflow turbine<ref name="C.Rodgers"/>
|fueltype=[[Gasoline]] or [[Diesel fuel]]
|oilsystem=pressure spray
|power=
|thrust={{convert|500|kp|kN lbf|abbr=on|order=flip}} at 11,600 rpm (at [[standard sea level|SSL]])<ref name="C.Rodgers"/>
|compression=2.8:1
|bypass=
|aircon=12.6 kg/s (27.7 lb/s)<ref name="C.Rodgers"/>
|turbinetemp=
|fuelcon=
|specfuelcon=
|power/weight=
|thrust/weight=
}}


==References==
==References==
{{reflist|30em}}
*''German Jet Engine and Gas Turbine Development'', Antony Kay, Airlife Books, 2002

* Lutz Warsitz: ''THE FIRST JET PILOT - The Story of German Test Pilot Erich Warsitz'', Pen and Sword Books Ltd., England, 2009, ISBN 9781844158188, [http://www.pen-and-sword.co.uk/?product_id=1762 English Edition]
==Bibliography==
*{{cite book |last1=Gunston |first1=Bill |title=World Encyclopedia of Aero Engines: From the Pioneers to the Present Day |date=2006 |publisher=Sutton |location=Stroud, UK |isbn=0-7509-4479-X |edition=5th}}
* {{cite book|last=Kay|first=Anthony L.|title=German Jet Engine and Gas Turbine Development 1930–1945 |publisher=The Crowood Press|date=2002|isbn=1-84037-294-X}}
*{{cite book|last=Kay|first=Anthony L.|title=Turbojet History and Development 1930–1960 |publisher=The Crowood Press|location=Ramsbury|date=2007|volume=1|isbn=978-1-86126-912-6}}
* Lutz Warsitz: ''The First Jet Pilot - The Story of German Test Pilot Erich Warsitz'', Pen and Sword Books, England, 2009, {{ISBN|978-1-84415-818-8}}
*''Military Turbojet/Turbofan Specifications'' [http://www.jet-engine.net/miltfspec.html] {{Webarchive|url=https://web.archive.org/web/20111002090707/http://www.jet-engine.net/miltfspec.html |date=2011-10-02 }}
*''Pioneering Turbojet Developments of Dr. Hans von Ohain — From the HeS 1 to the HeS 011'', Cyrus B. Meher-Homji and Erik Prisell, [http://proceedings.asmedigitalcollection.asme.org/proceeding.aspx?articleid=2084956], [http://proceedings.asmedigitalcollection.asme.org/data/conferences/asmep/81858/v001t01a005-99-gt-228.pdf]


==External links==
==External links==
{{Commonscat|Heinkel HeS 3‎}}
{{Commons category|Heinkel HeS 3}}
* [http://www.erichwarsitz.com The official '''Erich Warsitz''' website (the world's first jet pilot), inclusive rare videos (Heinkel He 178 & HeS 3 turbine) and audio commentaries]
* [http://www.erichwarsitz.com The official '''Erich Warsitz''' website (the world's first jet pilot), inclusive rare videos (Heinkel He 178 & HeS 3 turbine) and audio commentaries]


{{Hirth aeroengines}}
{{Hirth aeroengines}}
{{Aviation lists}}


{{DEFAULTSORT:Heinkel Hes 3}}
{{DEFAULTSORT:Heinkel Hes 3}}
[[Category:Turbojet engines 1930-1939]]
[[Category:Centrifugal-flow turbojet engines]]
[[Category:Heinkel aircraft engines]]

[[Category:1930s turbojet engines]]
[[de:Heinkel HeS 3]]
[[it:Heinkel HeS 3]]
[[ja:ハインケル HeS 3]]

Latest revision as of 19:31, 19 January 2024

HeS 3
A sectioned Heinkel HeS 3 Turbojet engine at the Deutsches Museum
Type Centrifugal flow turbojet engine
National origin Germany
Manufacturer Heinkel-Hirth Motorenwerke
First run 1939
Major applications Heinkel He 178
Developed from Heinkel HeS 1

The Heinkel HeS 3 (HeS - Heinkel Strahltriebwerke) was the world's first operational jet engine to power an aircraft. Designed by Hans von Ohain while working at Heinkel, the engine first flew as the primary power of the Heinkel He 178, piloted by Erich Warsitz on 27 August 1939. Although successful, the engine had too little thrust to be really useful, and work started on the more powerful Heinkel HeS 8 as their first production design.

Development

[edit]

The HeS 3 design was largely based on the HeS 1 but converted to burn liquid fuel instead of hydrogen gas used in the HeS 1. The first HeS 3 design was generally similar to the HeS 1, using an 8-blade inducer and 16-blade centrifugal compressor. The compressed air flowed into an annular combustion chamber between the compressor and turbine, which made the engine longer.[citation needed] The first example was bench tested around March 1938, but did not reach the design thrust because a small compressor and combustor had been used to reduce the frontal area.[1] Max Hahn, from Heinkel, applied May 31, 1939, for a US patent, granted Sept 16, 1941: 'Aircraft Power Plant', US2256198, with the von Ohain design.

An improved engine, the HeS 3b, had a 14-blade inducer and 16 blade centrifugal compressor. In order to minimise the diameter the widest part of the annular combustor was placed in line with the smaller diameter axial entry to the impeller. At exit from the impeller the air flowed forwards, then turned through 180 degrees to flow rearward through the combustor. The flow was then turned radially inwards to enter the turbine. Although not as compact as the original design, the 3b was much simpler. The fuel was used to cool rear roller bearing, which also preheated the fuel.[2]

The engine was completed in early 1939, and was flight-tested under one of the remaining Heinkel He 118 dive bomber prototypes. The flight tests were carried out in extreme secrecy, taking off and landing under propeller power, and only flying in the early morning before other workers had arrived. Testing proceeded smoothly, but the engine eventually burned out its turbine.

A second engine was completed just after completion of the He 178 airframe, so it was decided to move directly to full flight tests. A short hop was made on 24 August during high-speed taxi tests, followed by full flight on 27 August, the first aircraft to fly solely under jet power. Testing continued and in November the aircraft was demonstrated to RLM officials in hopes of receiving funding for the development of a larger engine, but nothing seemed forthcoming.

Hans Mauch later told von Ohain the RLM was in fact extremely impressed, but he was concerned that Heinkel's airframe team did not have the knowledge to undertake engine development. Instead he and Helmut Schelp secretly visited a number of aircraft engine manufacturers to try to start programs there. Mauch left his position in 1939 leaving Schelp in command. Schelp was not as concerned about where development was taking place, and immediately started funding Heinkel to produce a more powerful engine.

HeS 6

[edit]

Work on a larger version, the HeS 6, started immediately, and was tested under a Heinkel He 111 late in 1939. While successful, raising thrust just above 590 kp (1,300 lbf), weight increased from 360 to 420 kg. The diameter of the engines remained too large to directly substitute the planned HeS 30 (109-006) engines on the He 280 fighter, therefore the design was abandoned in favour of the more compact Heinkel HeS 8 utilizing a straight-through flow combustion layout.

Specifications (HeS 3b)

[edit]

Data from [3]

General characteristics

  • Type: Centrifugal flow turbojet engine
  • Length: 1,480 mm (58 in)
  • Diameter: 930 mm (37 in)
  • Dry weight: 360 kg (790 lb)

Components

Performance

References

[edit]
  1. ^ "Pioneering Turbojet Developments of Dr. Hans Von Ohain-From the HeS 1 to the HeS 011" Meher-Homji and Prisell, Transactions of the ASME, Vol. 122, April 2000
  2. ^ a b c d e f "A Performance Diagnosis of the 1939 Heinkel HE S3B Turbojet" C. Rodgers, GT2004-53014
  3. ^ Kay 2007, pp. 171–174

Bibliography

[edit]
  • Gunston, Bill (2006). World Encyclopedia of Aero Engines: From the Pioneers to the Present Day (5th ed.). Stroud, UK: Sutton. ISBN 0-7509-4479-X.
  • Kay, Anthony L. (2002). German Jet Engine and Gas Turbine Development 1930–1945. The Crowood Press. ISBN 1-84037-294-X.
  • Kay, Anthony L. (2007). Turbojet History and Development 1930–1960. Vol. 1. Ramsbury: The Crowood Press. ISBN 978-1-86126-912-6.
  • Lutz Warsitz: The First Jet Pilot - The Story of German Test Pilot Erich Warsitz, Pen and Sword Books, England, 2009, ISBN 978-1-84415-818-8
  • Military Turbojet/Turbofan Specifications [1] Archived 2011-10-02 at the Wayback Machine
  • Pioneering Turbojet Developments of Dr. Hans von Ohain — From the HeS 1 to the HeS 011, Cyrus B. Meher-Homji and Erik Prisell, [2], [3]
[edit]