Through use, gas turbine engines become subject to buildup of contaminants on engine components. These contaminants can affect engine components and overall performance of the engine. Engine washing can help to remove these contaminants and improve engine performance and efficiency.
Conventional compressor washing can be done by introducing a fluid to the inlet of the engine, with the intention of it flowing through the compressor and removing contaminants therein. Conventional turbine wash processes are accomplished periodically by removing an igniter, installing a cleaning probe into an ignitor port and flushing out the igniter port with a wash fluid. After cleaning of the turbine is complete, the cleaning probe is removed and the igniter is reinstalled.
An engine wash system includes a manifold for delivering wash liquid to an engine. The manifold includes an internal engine contour segment shaped to correspond with at least a portion of the engine case at the inlet; a wash delivery segment connected to the internal engine contour segment which follows the engine case curvature in an axial direction and hooks around an outside of the engine case at the inlet; an inlet on the wash delivery segment to receive wash fluid; a nozzle on the wash delivery portion directed to spray into the compressor inlet of the engine; and a guide extending from the pipe and shaped to align the manifold with respect to the engine so that the nozzle sprays into the engine aft of the inlet particle separator.
A method of washing an engine includes securing a manifold with a nozzle to the engine by inserting an internal engine contour segment of the manifold into an inlet of the engine case so that a first end of a wash delivery segment wraps around to an outside of the engine case and a second end of the wash delivery segment of the manifold extends axially into the engine and a guide rests between two inlet guide vanes; delivering wash fluid to an inlet on the manifold; flowing the wash fluid through the wash delivery segment to a nozzle on the second end; and directing the wash fluid through the nozzle at the compressor inlet.
Manifold 10 is shaped to hold nozzle securely in place for an engine 12 wash operation. Manifold 10 can be made of metal, such as stainless steel and coated in part or in whole with a polymer type coating to prevent scratching or marring of surfaces when attaching manifold 10 to engine 12.
Internal engine contour segment 28 of manifold 10 is shaped to correspond with at least a portion of inner wall 18 of case 14 of engine 12. In the embodiment of manifold 10 shown, internal engine contour segment 28 connects to wash delivery segment 30 in the center and extends on both sides of the connection to follow the curvature of inner wall 18 of case 14 to securely stabilize manifold in a radial direction.
In the embodiment shown, nozzle 40 sprays perpendicular to second end portion 36 of pipe 32, but in other embodiments it may be oriented or directed differently. Nozzle could be a flat spray nozzle or any type of nozzle desired for the specific engine washing operation. Nozzle 40 can atomize wash liquid and can vary to direct water at different pressures, droplet sizes, temperatures and flow rates.
Wash delivery segment 30 of manifold 10 comprises pipe 32 to receive and deliver wash fluid to engine 12. Pipe 32 has first end portion 34 shaped to hook around outer wall 16 of engine 12 case 14. Pipe 32 extends perpendicular to internal engine contour segment 28, and second end portion 36 includes nozzle 40. Wash delivery segment 30 is shaped to follow the contour of inner wall 18 of engine case 14 in an axial direction so that when put in place to perform a washing operation, nozzle 40 is directed toward compressor inlet 22.
As shown in
To wash engine 12, manifold 10 is placed in engine 12 as shown in
Once manifold 10 has been positioned with respect to engine 12, an engine washing operation can begin. Inlet 38 can receive wash liquid, which can be heated, deionized water only or could include detergent to help with the cleaning process, depending on system needs and requirements. Wash liquid can be temperature regulated for more efficient washing processes by using a heater to increase the temperature, isopropyl alcohol to keep wash liquid from freezing in cold weather or other means depending on system requirements. Wash liquid can be delivered from a hose connected to a wash unit (see
Wash liquid travels through hollow pipe 32 of wash delivery segment 30 to nozzle 40. Nozzle 40 directs the wash liquid into compressor inlet 22 to remove contaminants and buildup in compressor. During a wash operation, engine can be cranked to assist in flowing wash liquid through engine 12 in the same manner that air and contaminants flow through engine. For washing operations, it may be desirable to motor engine with starter or auxiliary power unit.
Helicopters are flown in various harsh environments where they encounter dirt, sand and a variety of other contaminants which can lead to quick soiling of the engine. To minimize contaminants entering engine 12, inlet particle separator 26 is located forward of compressor inlet 22 to prevent unwanted dirt and fluids from entering compressor inlet 22. As mentioned above, past wash systems generally introduced a low pressure (for example, 60 psi) cleaning fluid to engine inlet. This resulted in part of the cleaning fluid exiting the inlet particle separator prior to entering compressor, and thus decreasing the effectiveness of the wash spray.
Manifold 10 can effectively wash engine 12 by securing manifold 10 to engine 12 with internal engine contour segment 28 and wash delivery segment 30 so that nozzle 40 is positioned at compressor inlet 22, aft of inlet particle separator 26. This ensures that all of wash liquid delivered to inlet 38 enters compressor inlet 22 to clean engine 12. Internal engine contour segment 28 and wash delivery segment 30 are shaped to follow the contours of engine 12 case 14 to ensure manifold 10 is held securely in place during a wash operation. Guide 42 and strap 44 work to ensure further security and alignment of manifold 10. Manifold 10 can provide a successful and efficient wash for aircraft engine 12, which can increase overall engine performance by decreasing engine temperature, reducing fuel consumption, increasing engine power and improving overall engine efficiency and extending the time until the engine needs to be overhauled. A clean engine 12 can also result in fewer harmful engine 12 emissions by reducing fuel consumption while restoring efficiency, overall performance and increasing life of engine 12.
Engine wash unit 50 can include equipment for generating power, storing, heating pumping, delivering, spraying, collecting, treating and filtering wash liquid. This can include hoses, a generator, a heater, a pump and/or the manifold shown in
Collection pan 54 includes a base 62 angled toward centerline 63, with ribs 65 and outlet 67 at center line 63 to drain wash fluid out of collection pan. While three ribs 65 are shown, collection pan 54 could include more or fewer ribs 65. Collection pan 54 has extendable sides with first panel 64 and second panel 66. First panel 64 is rotatably connected to first side 58 of collection pan 54, and second panel 66 is rotatably connected to second side 60 of collection pan 62. First panel 64 and second panel 66 can be rotated outward (see
Vertical support piece 86 of first support 68 connects to front 56 of collection pan 54 near first side 58. Horizontal support piece 88 connects to an upper end of vertical support piece 86 and to first funnel 70 to support first funnel 70. The connection between horizontal support piece 88 and funnel 70 can be a rotatable support allowing funnel 70 to rotate. First hose 72 connects to first funnel and to collection pan 54. Second funnel 76 is connected to and supported by horizontal support piece 92, which connects to vertical support piece 90. The connection between horizontal support piece 92 and second funnel 76 can also be a rotatable support, allowing funnel 76 to rotate. Vertical support piece 90 of second support 74 connects to front 56 of collection pan 54 near second side 60. Second hose 78 connects to second funnel 76 and to collection pan 54. Vertical support pieces 86, 90 and horizontal support pieces 88, 92 are adjustable in the vertical and horizontal direction, for example, by using telescoping supports and/or having a slideable connection between vertical support pieces 86, 90 and horizontal support pieces 88, 92. In the embodiment shown, funnels 70, 76 are square shaped and the base is angled to drain into hoses 72, 78.
First support 68, first funnel 70, first hose 72, second support 74, second funnel 76, and second hose 78 can detach from collection pan 54 and can be placed within base 62 on ribs 65 for transport or storage, as shown in
The wash fluid exiting engine 12 during a wash operation may contain contaminants requiring collection of the effluent for proper disposal or treatment. Collector acts to collect wash fluid draining from an engine wash procedure. First funnel 70 and second funnel 76 are located to collect wash fluid draining from engine cases 14 and collection pan 54 with panels 64, 66 collect wash fluid draining from the exhaust. Collection pan 54 can empty through outlet 67 into a drain through a hose (not shown) or can feed wash effluent into a system to treat the wash effluent and reclaim clean liquid for washing operations. The treatment system could be located in engine wash unit 50.
Collector 52 is an effective an efficient way to collect used wash liquid. Collector 52 is also compact and easy to transport and store by using detachable first support 68, first funnel 70, first hose 72, second support 74, second funnel 76 and second hose 78, which are able to fit inside collection pan 54 under rotatable panels 64, 66.
Manifold 10 can be connected to engine 12 inlet 14, as described in relation to
Collector 52 can be set up (as shown in
Wash system 100 sends wash liquid to manifolds 10 through hose 94. Manifolds 10 direct that wash liquid into compressor inlets (see
Wash system 100 using manifolds 10 and collector 52 can effectively wash all engines 12 of aircraft 53 and collect wash liquid exiting engines 12 through all main exit points simultaneously, allowing for an efficient and effective wash procedure. Manifolds 10 effectively introduce wash liquid into engine to clean engine by spraying aft of inlet particle separator, therefore ensuring a more effective wash. Collector 52 collects all streams of wash effluent by using collection pan 54 with panels 64, 66 and funnels 70, 76, allowing for collection from both aircraft engines 12 simultaneously, and therefore allowing both engines to be washed at the same time. Collector 52 is also collapsible, allowing for easy transport and storage due to its compact configuration with all components detachable and able to fit inside collection pan 54. Wash system 100 provides a robust and effect wash system for H-60 aircraft 53, that can be a closed loop system (with wash unit 50), which can wash engine 12, collect the used wash liquid, and remove contaminants from the used wash liquid to prepare it for reuse in washing operations. Engine wash system 100 is compact and portable, allowing for use wherever needed.
The use of a Sikorsky H-60 helicopter engine is for example purposes only, and engine wash manifold 10 and/or collector 52 can be used with other aircrafts and/or engines.
While collector 52 has been shown to use funnels 70, 76 with supports 68, 74 and hoses 72, 78, alternate embodiments could include flexible ducts and/or hoses directly connecting places where wash effluent would exit to collection pan 10.
An engine wash system includes a manifold for delivering wash liquid to an engine. The manifold includes an internal engine contour segment shaped to correspond with at least a portion of the engine case at the inlet; a wash delivery segment connected to the internal engine contour segment which follows the engine case curvature in an axial direction and hooks around an outside of the engine case at the inlet; an inlet on the wash delivery segment to receive wash fluid; a nozzle on the wash delivery portion directed to spray into the compressor inlet of the engine; and a guide extending from the pipe and shaped to align the manifold with respect to the engine so that the nozzle sprays into the engine aft of the inlet particle separator.
Additional and/or alternative embodiments include the guide connecting radially to the pipe and bending toward the first end to sit against between two inlet guide vanes; the manifold being coated with a polymeric coating, the nozzle spraying directly into the compressor; a strap to connect to the first end of the wash delivery segment and to an external engine component; a wash unit to deliver the wash fluid to the manifold inlet; the wash unit being mobile; a collector for collecting wash liquid from the engine washing operation; the collector comprising a collection pan with a base angled toward a centerline and extendable sides; a plurality of wheels connecting to the base; a first support connecting on a lower end to the collection pan and extending vertically upward from the collection pan; a first funnel connecting to the first support; a first hose connecting the first funnel to the collection pan; a second support connecting on a lower end to the collection pan and extending vertically upward from the collection pan; a second funnel connecting to the second support; and a second hose connecting the second funnel to the collection pan; the first support being connected at a front end and near the first side of the collection pan and the second support being connected at a front end and near the second side of the collection pan; the first support, the first funnel, the first hose, the second support, the second funnel and the second hose being able to disconnect from the collection pan, be placed inside the collection pan and the first and second sides can rotate to cover the collection pan with the first support, the first funnel, the first hose, the second support, the second funnel and the second hose inside the collector further comprising a tow bar for moving the collector; and/or the extendable sides of the collector each comprising first and second rotatable panels connected to first and second sides of the collection pan.
A method of washing an engine includes securing a manifold with a nozzle to the engine by inserting an internal engine contour segment of the manifold into an inlet of the engine case so that a first end of a wash delivery segment wraps around to an outside of the engine case and a second end of the wash delivery segment of the manifold extends axially into the engine and a guide rests against two inlet guide vanes; delivering wash fluid to an inlet on the manifold; flowing the wash fluid through the wash delivery segment to a nozzle on the second end; and directing the wash fluid through the nozzle at the compressor inlet.
Additional and/or alternative embodiments include securing the manifold to the engine so that the nozzle on the second end is located axially aft of the inlet particle separator; connecting a strap between the wash delivery segment and another aircraft component; collecting the used wash liquid exiting the engine; collecting wash liquid from engine exhaust with a collection pan with rotatable side panels and collecting wash liquid from engine cases with funnels connected to the connection pan by adjustable supports and hoses; treating the collected wash liquid and/or delivering the treated wash liquid back to the manifold inlet to be used for washing.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
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