US2763155A - High altitude burner simulator - Google Patents

High altitude burner simulator Download PDF

Info

Publication number
US2763155A
US2763155A US99258A US9925849A US2763155A US 2763155 A US2763155 A US 2763155A US 99258 A US99258 A US 99258A US 9925849 A US9925849 A US 9925849A US 2763155 A US2763155 A US 2763155A
Authority
US
United States
Prior art keywords
conduit
pressure
chamber
air
section
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US99258A
Inventor
Jesse W Beams
Leland B Snoddy
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to US99258A priority Critical patent/US2763155A/en
Application granted granted Critical
Publication of US2763155A publication Critical patent/US2763155A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23RGENERATING COMBUSTION PRODUCTS OF HIGH PRESSURE OR HIGH VELOCITY, e.g. GAS-TURBINE COMBUSTION CHAMBERS
    • F23R3/00Continuous combustion chambers using liquid or gaseous fuel

Definitions

  • the present invention relates to apparatus and procedures for simulating conditions prevailing in high-altitude regions of the earths atmosphere, for the purpose of testing ram-jet burners and combustion under such conditions.
  • An object of the present invention is to provide a system free from mechanical pumps and other moving mechanism for maintaining a low pressure atmosphere for combustion experiments and tests.
  • Another object is to provide a system of this type, wherein a two-stage ejector is utilized to maintain such low pressure atmosphere.
  • a further object is to provide means having ample air handling capacity, whereby the necessary low pressure may be maintained in spite of a relatively great flow of combustion products resulting from the tests,
  • An additional object is to provide a system of this type. wherein the air supplied to the device being tested may be preheated to a controllable extent.
  • Fig. 1 is a diagram of the complete apparatus, certain portions being shown in axial section;
  • Fig. 2 is an axial section, on a larger scale, through the pressure chamber, parts being broken away;
  • Fig. 3 is a cross section of the pressure chamber in the plane 33 of Fig. 2;
  • Fig. 4 is a cross section of the pressure chamber in the plane 44 of Fig. 2. 7
  • the apparatus comprises a pressure chamber 1 wherein a high pressure is produced by the combustion of fuel, such as gasoline, in compressed air.
  • fuel such as gasoline
  • the gasoline may be introduced through a pipe 7, and the compressed air enters through a pipe 2, from any suitable source, such as an air compressor, not shown.
  • a pressure gage 6 may be connected to pipe 2, if desired.
  • the pressure chamber 1 has two important functions: It supplies a high velocity flow of combustion products, to operate a two-stage ejector, and it preheats the air that is to be supplied to the simulated ram-jet that is being tested.
  • the ejector system is designated as a whole by reference character 8. It comprises a first stage pump 9, having a relatively large nozzle 11, preferably in substantial axial alinement with the pressure chamber 1, and fed from its large outlet conduit 14, as shown, and a sec? 0nd stage pump 10, having a smaller nozzle 12, fed from a branch conduit 13 connected to said conduit 14.
  • the ejectors 9 and 10 will operate in a more or less conventional way to exhaust the contents of conduits 15 and 16, Pressure gages 17, 18 and 19, of the Bourdon type, or any other suitable manometers, may be provided as shown, to indicate the pressures prevailing in the various parts of the ejector system.
  • the ram-jet to be tested is simulated by a conduit 20.
  • a plate 21 having an orifice 22, through which air for combustion is introduced into the conduit 20 from the pipe 23.
  • This pipe has an inlet pipe 24 at one end, through which atmospheric air enters.
  • Within the chamber 1 there is an air heating section, which will be described later.
  • the pipe 23 thus delivers heated air through the orifice 22, when valve 26 is open.
  • a branch pipe 25, with a valve 27, is connected to pipe 23 as shown, and may be used to admit cold air tothe orifice plate, that is, air at atmospheric temperature. By manipulation of both valves, air at controlled temperatures'may thus be supplied to the simulated ram-jet.
  • a manometer 28 and a temperature measuring device 29 may be provided to indicate the pressure and temperature of the air supplied through the orifice.
  • the pressure in the ram-jet is shown by the manometer 32. Combustion is initiated and maintained by a suitable pilot, an electric are 3.3 being here shown for this purpose.
  • the ejector system maintains a suitable low pressure at the outlet end of the ram-jet, simulating atmospheric pressure at high altitude.
  • one pressure chamber now in successful operation is about eighteen inches in inside diameter and thirteen feet long.
  • compressed air is introduced through pipe 2 at a suitable pressure, for example 60 lbs. per sq. in., from any conventional source.
  • An oil burner nozzle 5 such as is commonly usedin domestic oil burners, is provided for preheating the chamber 1, and its contents, when it is to be put into operation.
  • Refractory baflles 36, 37 are mounted within the chamber. These bafiles, only two of which are shown, are of semicircular shape, and located alternately on opposite sides of the chamber, with their flat diametrically located surfaces substantially in one plane, so that the hot gases generated by the combustion of the gasoline from nozzle 34 must follow a zig-zag orsinuous course through the bafiie region of the chamber.
  • bafiles may be provided, preferably at least four. They are made of massive ceramic material and successive baffles are spaced apart a distance approximately equal to the thickness of each baffle, about four inches in the present example. While the baifies are shown alternately above and below the horizontal axial plane in Fig. 2, this was done merely to facilitate the understanding of the structure, and in practice the fiat diametrically located surfaces will preferably be vertical instead of horizontal, because it simpler to support them in the vertical positions mentioned, Any suitable supports for the baffles may be provided. Semicircular angle iron brackets 38 are shown as one possible way.
  • Igniting means for the gasoline are shown at 39.
  • These igniters are oxy-hydrogen burners, located near the opposite corners of the first bafile. A flame of this kind is chosen because it is diflicult to blow out, in spite of the turbulence and high velocities of gases encountered in the pressure chamber.
  • These pilots or igniters may be themselves ignited in any conventional way, as by an electric spark or the like.
  • a safety valve 40 is mounted on a spud 41 near the gasoline nozzle 34. This valve is shown hinged at 42 and releasably latched at 43, to yield upon excessive pressure in the pressure chamber.
  • a safety shield 44 encloses the whole, and conducts the discharged gases away from the chamber and the personnel operating the latter.
  • the air heater section comprises an arbitrary number of U-shaped pipes 45, 46, 47, each connected at one end to the intake manifold 48 and at its other end to the discharge manifold 49.
  • the cold air at atmospheric temperature and pressure, is introduced into manifold 48 through pipe 24, and the heated air is discharged from manifold 49 into pipe 23, already discussed.
  • the first step is to preheat the pressure chamber, by means of the oil burner 5. This gradually heats the chamber and its contents, and prevents the sudden thermal shock that would result from starting at once with the large gasoline flame. In this way the life of the ceramic bafiies is conserved, and cracking thereof becomes less likely.
  • the preheating is also beneficial in preventing undue strains in the piping and joints.
  • the air pressure delivered through conduit 2 may be increased to its full value, and the nozzle 34 may be supplied with gasoline through pipe 7. This will ignite from the pilots 39 and also will be relit thereby whenever it fails for any reason.
  • bafiles 36, 37, etc. will guide the combustion products in a tortuous course, thoroughly mixing them and equalizing the flow and temperature fluctuations to a certain extent.
  • the air passing through the pipes 45, 46, 47 will become heated, and will supply hot air to the simulated ram-jet 20, thus simulating the conditions of actual operation of such jet at supersonic speeds, whereby the shock wave at the mouth of the jet provides hot air.
  • the ejectors 9 and '10 maintain a suitably low pressure at the tail-pipe end of the ram-jet, simulating high altitude atmospheric conditions.
  • the valves and manometers afford a certain degree of control of the operating conditions, as will be obvious.
  • Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit having an open end exposed to atmospheric air, a section intermediate the ends of said conduit simulating a ramjet, a chamber in which high pressure gases are formed by combustion, a portion of said conduit between said open end and said section extending through said chamber for supplying preheated air to one end of said section of conduit, and exhaust means connected to said chamber and positioned adjacent the other end of said section of conduit for maintaining a reduced pressure at said other end.
  • Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit open at one end to atmospheric pressure, a section intermediate the ends of said conduit simulating a ramjet, a chamber in which gases under pressure are formed by combustion, a portion of said conduit between said open end and said section extending through said chamber for supplying preheated air to one end of said section of conduit, and a two stage ejector pump connected to said chamber and arranged adjacent the other end of said section of conduit for maintaining a reduced pressure immediately beyond said other end.
  • Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit open at one end to atmospheric pressure, said conduit being provided at a point along its length with an orifice, the section of conduit following said orifice being utilized to simulate a ramjet, a combustion chamber for generating gas under pressure, a portion of the conduit between said open end and said orifice extending through said combustion chamber for supplying preheated air through said orifice to said section of conduit thereby simulating conditions at a ramjet intake, means for supplying fuel to the section of conduit following said orifice for mixing with said preheated air, means for igniting the fuel-air mixture in said section of conduit, and an exhaust pipe connected to said combustion chamber and positioned adjacent the other end of said conduit thereby providing an ejector for maintaining a reduced pressure immediately beyond said section of conduit simulating conditions at the exhaust of a ramjet.
  • An apparatus for simulating the operating conditions of a ramjet in altitude flight comprising a conduit having one end open to atmospheric pressure, and an outlet at the other end, said conduit being provided with a reduced orifice intermediate its ends, a section of said conduit following said orifice simulating a ramjet, means for supplying fuel to said simulated ramjet section, a combustion chamber, a portion of said conduit between said open end and said simulated ramjet section extending through said chamber and supplying preheated air to said simulated ramjet section, means for igniting the air-fuel mixture contained therein, and exhaust means including an ejector connected to said combustion chamber and positioned adjacent said outlet end of said conduit for removing gases from said simulated ramjet section.

Description

Sept. 18, 1956 J. w. BEAMS ET AL HIGH ALTITUDE BURNER SIMULATOR 2 Sheets-Sheet 1 Filed June 15, 1949 INVENTOR. JESSE W BEAMS LELAND B. SNODDY mm N 3 23 253 5 om Emma Emma om ATTORNEY Sept. 18, 1956 J. w. BEAMS EI'AL HIGH ALTITUDE BURNER SIMULATOR Filed June 15, 1949 2 Sheets-Sheet 2 INVENTOR.
JESSE W. BEAMS LELAND B. SNODDY ATTORNEY United States Patent Oflfice 2,763,155 Patented Sept,- 18, 19.56
2,763,155 HIGH ALTITUDE BURNER SIMULATOR Jesse W. Beams and Leland B. Snoddy, Charlottesville,
Va., assignors to the United 'States of America as represented by the Secretary of the Navy Application June 15, 1949, Serial No. 99,258
4 Claims. (Cl. 73116) The present invention relates to apparatus and procedures for simulating conditions prevailing in high-altitude regions of the earths atmosphere, for the purpose of testing ram-jet burners and combustion under such conditions.
The importance of such testing is due to the development of ram-jet vehicles, which operate at high altitudes and wherein combustion of the motor fuel therefor occurs in a low-pressure atmosphere. It will be obvious that combustion will be modified profoundly by such conditions, and that it is not at all certain that fuels and fuelzair mixtures at ratios that are highly satisfactory at or near sea-level, will perform properly, or even burn at all, under low-pressure conditions. It is also possible that similar remarks apply to the burners themselves. Heretofore no suitable procedures or facilities for testing fuels and burners under such conditions have been available.
An object of the present invention is to provide a system free from mechanical pumps and other moving mechanism for maintaining a low pressure atmosphere for combustion experiments and tests.
Another object is to provide a system of this type, wherein a two-stage ejector is utilized to maintain such low pressure atmosphere.
A further object is to provide means having ample air handling capacity, whereby the necessary low pressure may be maintained in spite of a relatively great flow of combustion products resulting from the tests,
An additional object is to provide a system of this type. wherein the air supplied to the device being tested may be preheated to a controllable extent.
Other objects and many of the attendant advantages of this invention will be appreciated readily as the same becomes understood by reference to the following detailed description, when considered in connection with the accompanying drawings, wherein:
Fig. 1 is a diagram of the complete apparatus, certain portions being shown in axial section;
Fig. 2 is an axial section, on a larger scale, through the pressure chamber, parts being broken away;
Fig. 3 is a cross section of the pressure chamber in the plane 33 of Fig. 2; and
Fig. 4 is a cross section of the pressure chamber in the plane 44 of Fig. 2. 7
Referring first to Fig. 1', the apparatus comprises a pressure chamber 1 wherein a high pressure is produced by the combustion of fuel, such as gasoline, in compressed air. The gasoline may be introduced through a pipe 7, and the compressed air enters through a pipe 2, from any suitable source, such as an air compressor, not shown. A pressure gage 6 may be connected to pipe 2, if desired.
The pressure chamber 1 has two important functions: It supplies a high velocity flow of combustion products, to operate a two-stage ejector, and it preheats the air that is to be supplied to the simulated ram-jet that is being tested. The ejector system is designated as a whole by reference character 8. It comprises a first stage pump 9, having a relatively large nozzle 11, preferably in substantial axial alinement with the pressure chamber 1, and fed from its large outlet conduit 14, as shown, and a sec? 0nd stage pump 10, having a smaller nozzle 12, fed from a branch conduit 13 connected to said conduit 14.
Assuming that an adequate supply of gaseous combus tion products is delivered from the pressure tank 1 through conduit 14, the ejectors 9 and 10 will operate in a more or less conventional way to exhaust the contents of conduits 15 and 16, Pressure gages 17, 18 and 19, of the Bourdon type, or any other suitable manometers, may be provided as shown, to indicate the pressures prevailing in the various parts of the ejector system.
The ram-jet to be tested is simulated by a conduit 20. At its intake end there is a plate 21 having an orifice 22, through which air for combustion is introduced into the conduit 20 from the pipe 23. This pipe has an inlet pipe 24 at one end, through which atmospheric air enters. Within the chamber 1 there is an air heating section, which will be described later. The pipe 23 thus delivers heated air through the orifice 22, when valve 26 is open. A branch pipe 25, with a valve 27, is connected to pipe 23 as shown, and may be used to admit cold air tothe orifice plate, that is, air at atmospheric temperature. By manipulation of both valves, air at controlled temperatures'may thus be supplied to the simulated ram-jet. A manometer 28 and a temperature measuring device 29 may be provided to indicate the pressure and temperature of the air supplied through the orifice.
A fuel supply pipe 30, having a suitable nozzle 31 within the ram-jet 20, supplies the fuel to be tested. The pressure in the ram-jet is shown by the manometer 32. Combustion is initiated and maintained by a suitable pilot, an electric are 3.3 being here shown for this purpose. The ejector system maintains a suitable low pressure at the outlet end of the ram-jet, simulating atmospheric pressure at high altitude.
.The details of the pressure chamber 1 will now be described, with especial reference to Figs. 2, 3 and 4.
Without, limiting the dimensions of the chamber thereto, but purely by way of example, it may be said that one pressure chamber now in successful operation. is about eighteen inches in inside diameter and thirteen feet long.
At its air intake end, compressed air is introduced through pipe 2 at a suitable pressure, for example 60 lbs. per sq. in., from any conventional source. An oil burner nozzle 5, such as is commonly usedin domestic oil burners, is provided for preheating the chamber 1, and its contents, when it is to be put into operation.
W t n t e ch mbe a as e nozzle 34 upplied from the pipe 7. Refractory baflles 36, 37, are mounted within the chamber. These bafiles, only two of which are shown, are of semicircular shape, and located alternately on opposite sides of the chamber, with their flat diametrically located surfaces substantially in one plane, so that the hot gases generated by the combustion of the gasoline from nozzle 34 must follow a zig-zag orsinuous course through the bafiie region of the chamber.
' It will be understood that any desired number of bafiles may be provided, preferably at least four. They are made of massive ceramic material and successive baffles are spaced apart a distance approximately equal to the thickness of each baffle, about four inches in the present example. While the baifies are shown alternately above and below the horizontal axial plane in Fig. 2, this was done merely to facilitate the understanding of the structure, and in practice the fiat diametrically located surfaces will preferably be vertical instead of horizontal, because it simpler to support them in the vertical positions mentioned, Any suitable supports for the baffles may be provided. Semicircular angle iron brackets 38 are shown as one possible way.
Igniting means for the gasoline are shown at 39. These igniters are oxy-hydrogen burners, located near the opposite corners of the first bafile. A flame of this kind is chosen because it is diflicult to blow out, in spite of the turbulence and high velocities of gases encountered in the pressure chamber. These pilots or igniters may be themselves ignited in any conventional way, as by an electric spark or the like.
A safety valve 40 is mounted on a spud 41 near the gasoline nozzle 34. This valve is shown hinged at 42 and releasably latched at 43, to yield upon excessive pressure in the pressure chamber. A safety shield 44 encloses the whole, and conducts the discharged gases away from the chamber and the personnel operating the latter.
The air heater section comprises an arbitrary number of U-shaped pipes 45, 46, 47, each connected at one end to the intake manifold 48 and at its other end to the discharge manifold 49. The cold air, at atmospheric temperature and pressure, is introduced into manifold 48 through pipe 24, and the heated air is discharged from manifold 49 into pipe 23, already discussed.
For strength, and prevention of leakage, it is preferred to make the pipe connections with the customary threads, wherever feasible, and to provide additional security and tightness by welding around all joints in the entire apparatus, as shown.
The operation will presumably be clear from the description of the structure, but may be summarized briefly as follows:
When the apparatus is to be put into service, the first step is to preheat the pressure chamber, by means of the oil burner 5. This gradually heats the chamber and its contents, and prevents the sudden thermal shock that would result from starting at once with the large gasoline flame. In this way the life of the ceramic bafiies is conserved, and cracking thereof becomes less likely. The preheating is also beneficial in preventing undue strains in the piping and joints.
After the chamber has reached a relatively high temperature from this preheating, the air pressure delivered through conduit 2 may be increased to its full value, and the nozzle 34 may be supplied with gasoline through pipe 7. This will ignite from the pilots 39 and also will be relit thereby whenever it fails for any reason.
The bafiles 36, 37, etc. will guide the combustion products in a tortuous course, thoroughly mixing them and equalizing the flow and temperature fluctuations to a certain extent.
The air passing through the pipes 45, 46, 47 will become heated, and will supply hot air to the simulated ram-jet 20, thus simulating the conditions of actual operation of such jet at supersonic speeds, whereby the shock wave at the mouth of the jet provides hot air.
The ejectors 9 and '10 maintain a suitably low pressure at the tail-pipe end of the ram-jet, simulating high altitude atmospheric conditions. The valves and manometers afford a certain degree of control of the operating conditions, as will be obvious.
Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.
What is claimed is:
1. Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit having an open end exposed to atmospheric air, a section intermediate the ends of said conduit simulating a ramjet, a chamber in which high pressure gases are formed by combustion, a portion of said conduit between said open end and said section extending through said chamber for supplying preheated air to one end of said section of conduit, and exhaust means connected to said chamber and positioned adjacent the other end of said section of conduit for maintaining a reduced pressure at said other end.
2. Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit open at one end to atmospheric pressure, a section intermediate the ends of said conduit simulating a ramjet, a chamber in which gases under pressure are formed by combustion, a portion of said conduit between said open end and said section extending through said chamber for supplying preheated air to one end of said section of conduit, and a two stage ejector pump connected to said chamber and arranged adjacent the other end of said section of conduit for maintaining a reduced pressure immediately beyond said other end.
3. Apparatus for simulating the operating conditions of a ramjet in high altitude flight comprising a conduit open at one end to atmospheric pressure, said conduit being provided at a point along its length with an orifice, the section of conduit following said orifice being utilized to simulate a ramjet, a combustion chamber for generating gas under pressure, a portion of the conduit between said open end and said orifice extending through said combustion chamber for supplying preheated air through said orifice to said section of conduit thereby simulating conditions at a ramjet intake, means for supplying fuel to the section of conduit following said orifice for mixing with said preheated air, means for igniting the fuel-air mixture in said section of conduit, and an exhaust pipe connected to said combustion chamber and positioned adjacent the other end of said conduit thereby providing an ejector for maintaining a reduced pressure immediately beyond said section of conduit simulating conditions at the exhaust of a ramjet.
4. An apparatus for simulating the operating conditions of a ramjet in altitude flight, comprising a conduit having one end open to atmospheric pressure, and an outlet at the other end, said conduit being provided with a reduced orifice intermediate its ends, a section of said conduit following said orifice simulating a ramjet, means for supplying fuel to said simulated ramjet section, a combustion chamber, a portion of said conduit between said open end and said simulated ramjet section extending through said chamber and supplying preheated air to said simulated ramjet section, means for igniting the air-fuel mixture contained therein, and exhaust means including an ejector connected to said combustion chamber and positioned adjacent said outlet end of said conduit for removing gases from said simulated ramjet section.
References Cited in the file of this patent UNITED STATES PATENTS 1,879,366 Loraine Sept. 27, 1932 2,422,694 McCollum June 24, 1947 2,435,990 Weiler Feb. 17, 1948 2,592,322 Nerad Apr. 8, 1952 2,615,331 Lundgren Oct. 28, 1952 FOREIGN PATENTS 792,293 France Oct. 14, 1935 822,929 France Oct. 4, 1937 521,143 Great Britain Apr. 11, 1939 712,706 Germany Oct. 23, 1941 579,758 Great Britain Aug. 14, 1946 438,578 Italy Aug. 17, 1948 OTHER REFERENCES Aircraft Engineering, Aug. 1946, pgs. 261 to 263.
Jet Propulsion by V. C. Finch. (Pages 271 to 272), S. L. Call #TL709 F.5 (Reference Date: Nov. 1947.)
Scientific American, Nov. 1947, page 220.
N.A.C.A. Technical Note No. 1687, Aug. 1948, Aero Digest, Apr. 1949, pages 44-47 and -421.
US99258A 1949-06-15 1949-06-15 High altitude burner simulator Expired - Lifetime US2763155A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US99258A US2763155A (en) 1949-06-15 1949-06-15 High altitude burner simulator

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US99258A US2763155A (en) 1949-06-15 1949-06-15 High altitude burner simulator

Publications (1)

Publication Number Publication Date
US2763155A true US2763155A (en) 1956-09-18

Family

ID=22273969

Family Applications (1)

Application Number Title Priority Date Filing Date
US99258A Expired - Lifetime US2763155A (en) 1949-06-15 1949-06-15 High altitude burner simulator

Country Status (1)

Country Link
US (1) US2763155A (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2930226A (en) * 1954-05-26 1960-03-29 Spalding Dudley Brian Apparatus for the simulation of combustion
US2975632A (en) * 1957-06-04 1961-03-21 North American Aviation Inc Ducted nozzle testing apparatus
US3044301A (en) * 1960-07-28 1962-07-17 Willard H Bennett Space simulating device and method
US3205705A (en) * 1961-12-08 1965-09-14 Talley Lawrence Covington Gas turbine jet and rocket engine ground test exhaust system
US3225589A (en) * 1961-04-10 1965-12-28 Garrett Corp Apparatus for testing the principles of detonation combustion

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1879366A (en) * 1930-04-21 1932-09-27 David G Lorraine Ejector
FR792293A (en) * 1935-05-20 1935-12-26 Escher Wyss Ag Installation for testing engines, especially aircraft engines, under operating conditions
FR822929A (en) * 1936-06-12 1938-01-11 Blast furnace operating process
GB521143A (en) * 1938-10-06 1940-05-14 Bbc Brown Boveri & Cie Improvements in and relating to wind tunnels
DE712706C (en) * 1939-08-27 1941-10-23 Richard Katzmayr Dipl Ing Device for increasing the wind speed in wind tunnel systems
GB579758A (en) * 1945-02-01 1946-08-14 Power Jets Res & Dev Ltd Improvements relating to fluid duct intakes
US2422694A (en) * 1944-01-01 1947-06-24 Stewart Warner Corp Wall-mounted ram-type aircraft heater
US2435990A (en) * 1945-08-17 1948-02-17 Westinghouse Electric Corp Gas turbine lubricating oil cooling and air inlet deicing system
US2592322A (en) * 1948-09-02 1952-04-08 Gen Electric Rocket motor pumped supersonic wind tunnel
US2615331A (en) * 1949-03-03 1952-10-28 Foster Wheeler Corp Apparatus for testing aeronautical equipment

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1879366A (en) * 1930-04-21 1932-09-27 David G Lorraine Ejector
FR792293A (en) * 1935-05-20 1935-12-26 Escher Wyss Ag Installation for testing engines, especially aircraft engines, under operating conditions
FR822929A (en) * 1936-06-12 1938-01-11 Blast furnace operating process
GB521143A (en) * 1938-10-06 1940-05-14 Bbc Brown Boveri & Cie Improvements in and relating to wind tunnels
DE712706C (en) * 1939-08-27 1941-10-23 Richard Katzmayr Dipl Ing Device for increasing the wind speed in wind tunnel systems
US2422694A (en) * 1944-01-01 1947-06-24 Stewart Warner Corp Wall-mounted ram-type aircraft heater
GB579758A (en) * 1945-02-01 1946-08-14 Power Jets Res & Dev Ltd Improvements relating to fluid duct intakes
US2435990A (en) * 1945-08-17 1948-02-17 Westinghouse Electric Corp Gas turbine lubricating oil cooling and air inlet deicing system
US2592322A (en) * 1948-09-02 1952-04-08 Gen Electric Rocket motor pumped supersonic wind tunnel
US2615331A (en) * 1949-03-03 1952-10-28 Foster Wheeler Corp Apparatus for testing aeronautical equipment

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2930226A (en) * 1954-05-26 1960-03-29 Spalding Dudley Brian Apparatus for the simulation of combustion
US2975632A (en) * 1957-06-04 1961-03-21 North American Aviation Inc Ducted nozzle testing apparatus
US3044301A (en) * 1960-07-28 1962-07-17 Willard H Bennett Space simulating device and method
US3225589A (en) * 1961-04-10 1965-12-28 Garrett Corp Apparatus for testing the principles of detonation combustion
US3205705A (en) * 1961-12-08 1965-09-14 Talley Lawrence Covington Gas turbine jet and rocket engine ground test exhaust system

Similar Documents

Publication Publication Date Title
US4206593A (en) Gas turbine
US3009321A (en) Ceramic-lined pilots for turbo-jet combustors
US3691766A (en) Combustion chambers
CN109630314B (en) Cold start system and cold start method for air-breathing engine
US3366373A (en) Apparatus for adding heat to gas turbine exhaust
US1725914A (en) Device for propelling aircraft at high altitudes by direct fluid reaction
GB691068A (en) Fuel burning means for a gaseous-fluid propulsion jet
US2914912A (en) Combustion system for thermal powerplant
US2697482A (en) Apparatus for combustion of fluid fuel with oxygen
US2763155A (en) High altitude burner simulator
GB1427540A (en) Devices for prevapourising liquid fuel
CN209355237U (en) A kind of burning heater
GB693846A (en) Vaporizer-type combustion apparatus for gas turbine engines
US2998703A (en) Reso-jet igniter
US2635564A (en) Combustion system for pulverulent fuel
US3382679A (en) Jet engine with vaporized liquid feedback
GB791990A (en) Improvements in ignition devices for combustion chambers of engines and propulsion units
GB791268A (en) Improvements relating to the starting of gas turbine engines
US3124933A (en) Leroy stram
CN106838902B (en) A kind of supersonic speed combustion gas injector
US3075353A (en) Supersonic combustion
US2835109A (en) Igniter for ram-jet
US3397536A (en) Fuel nozzle assembly for gas turbine engines or the like
US2923288A (en) Safety combustion apparatus for aircraft
US3986817A (en) Grid burner pilot igniter