The present invention generally relates to vehicle engines, and more particularly relates to emergency oil systems and methods for a vehicle engine.
It is desirable that aircraft, and especially military aircraft, include a secondary lubrication system or “emergency oil system” to operate as a back-up lubrication system in the unlikely event that the primary lubrication system experiences a malfunction or, in the case of military aircraft, that the primary lubrication system is damaged during combat. Contemporary secondary lubrication systems are typically a redundant lubrication system that provides lubrication during the failure of the primary lubrication system. Specifically, the secondary lubrication system typically includes an amount of oil in addition to and separate from the oil for the primary lubrication system for use during operation of the secondary lubrication system. The inclusion of extra oil in the secondary lubrication system adds weight to the aircraft, which added weight is undesirable in aircraft applications.
Accordingly, it is desirable to provide emergency oil systems and methods that use oil from the primary lubrication system during operation. In other words, it is desirable to provide emergency oil systems and methods that reduces or eliminates extra oil. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
Various embodiments provide secondary lubrication systems for an engine including a primary lubrication system having a de-aeration oil tank for storing de-aerated oil. One secondary lubrication system comprises a first valve configured to be coupled to the de-aeration oil tank and configured to control the flow of the de-aerated oil stored in the de-aeration oil tank through the secondary lubrication system, and an oil supply line coupled to the de-aeration oil tank via the first valve and configured to be coupled to the engine.
Other embodiments provide engines for a vehicle. One engine comprises a primary lubrication system and secondary lubrication system coupled to the engine. The primary lubrication system comprises a de-aeration oil tank coupled to the engine and configured to store aerated oil until the oil is de-aerated, a first oil supply line coupled to the de-aeration oil tank and the engine, the first oil supply line configured to provide de-aerated oil to the engine, and a first valve coupled to the de-aeration oil tank and configured to control the flow of oil through the primary lubrication system. The secondary lubrication system comprises a second valve coupled to the de-aeration oil tank and configured to control the flow of oil through the secondary lubrication system, and a second oil supply line coupled to the engine and to the de-aeration oil tank via the second valve.
Methods for lubricating an engine including a primary lubrication system configured to store aerated oil in a de-aeration oil tank and a secondary lubrication system coupled to the de-aeration oil tank are also provided. One method comprises the steps of detecting a predetermined event in the engine, preventing the aerated oil from entering the primary lubrication system, and using the aerated oil in the secondary lubrication system to lubricate the engine.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and
The following detailed description of the invention is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the invention or the following detailed description of the invention.
Various embodiments provide secondary lubrication systems (e.g., emergency oil systems) and methods that use oil from the primary lubrication system during operation. That is, the secondary lubrication systems do not include or reduces the extra oil or lubricant, but rather, use at least a portion of the oil or lubricant in the primary lubrication system during, for example, an emergency loss of oil supply and/or pressure, engine start-up, engine shut-down, and/or during another pre-determined event that may benefit from additional lubrication or cooling.
Turning now to the figures,
Engine 110 may be configured to power an aircraft (e.g., an airplane, a helicopter, an unmanned or manned aerial vehicle, etc.), a motor vehicle (e.g., a car, a truck, a military vehicle, etc.), a marine vessel (e.g., a boat, a ship, a submarine, etc.), and/or the like. Engine 110 typically includes various moving components (not shown) that need to be lubricated and/or cooled during operation of engine 110.
Lubrication system 120 is configured to provide lubrication and/or cooling to the various moving components within engine 110 using, for example, oil or some other type of lubricant/coolant. At least in the illustrated example of
Oil tank 1210 is typically configured to store/hold oil that is deemed temporarily “unusable” by engine 110 for normal operation of engine 110. That is, as the oil in lubrication system 120 is used to lubricate and/or cool engine 110, the oil becomes aerated. As one skilled in the art understands, aerated oil does not perform well as a lubricant and/or coolant in engine 110 because aerated oil tends to have a lower overall density, such that there is less mass flow per unit volume. As such, aerated oil does not provide the desired lubrication and/or cooling effect on engine 110. As such, oil tank 1210 is configured to store/hold aerated oil while the air rises out of the oil and the oil becomes substantially de-aerated and deemed suitable for use in lubricating and/or cooling engine 110. Specifically, de-aerated oil tends to settle or accumulate toward the bottom of oil tank 1210 as the oil de-aerates. Once substantially de-aerated, the de-aerated oil is provided to engine 110 via oil pump 1220.
Oil pump 1220 is typically configured to provide the de-aerated oil that has accumulated toward the bottom of oil tank 1210 to the various components of engine 110 that need to be lubricated and/or cooled via oil supply line 1215, which is typically in the form of tubes, channels, and/or other cavities in engine 110. Once engine 110 has used the oil supplied via oil pump 1220 and oil supply line 1215 (i.e., the oil has become aerated and/or heated), the oil is returned to oil tank 1210 via scavenge pump 1230.
Scavenge pump 1230 is typically configured to provide the aerated oil that has been used to lubricate and/or cool the various components in engine 110 to oil tank 1210 via oil return line 1225, which is typically in the form of tubes, channels, and/or other cavities in engine 110. The aerated oil is temporarily stored/held in oil tank 1210 until the oil again becomes substantially de-aerated, accumulates toward the bottom of oil tank 1210, and the lubricating/cooling cycle repeats.
As discussed above, aerated oil is considered unusable for normal operation of an engine; however, in various embodiments of the present invention, aerated oil is deemed usable for an engine in predetermined situations. That is, various embodiments of the present invention use oil that may be considered otherwise unusable to lubricate and/or cool an engine.
With reference now to
Engine 210 may be any engine or power plant capable of powering an aircraft (e.g., an airplane, a helicopter, an unmanned or manned aerial vehicle, etc.), a motor vehicle (e.g., a car, a truck, a military vehicle, etc.), a marine vessel (e.g., a boat, a ship, a submarine, etc.), and/or the like. That is, engine 210 typically includes various moving components (not shown) that need to be lubricated and/or cooled during operation of engine 210.
Primary lubrication system 220 is configured to provide lubrication and/or cooling to the various moving components within engine 210 using, for example, oil or some other type of lubricant/coolant. At least in the illustrated example of
De-aeration oil tank 2210 is configured to store/hold oil at various stages of aeration. That is, de-aeration oil tank 2210 is configured to store/hold aerated oil until the oil becomes substantially de-aerated. In single oil tank configurations, de-aeration oil tank 2210 is the oil tank where oil is stored while de-aerating, and may also be referred to as oil tank 2210. Once substantially de-aerated, the de-aerated oil is provided to oil pump 2220 via a valve 2327, which oil is then provided to engine 210 via oil pump 2220.
Oil pump 2220 is configured to provide the de-aerated oil in de-aeration oil tank 2210 to the various components of engine 210 that need to be lubricated and/or cooled via oil supply line 2215, which may be in the form of tubes, channels, and/or other cavities in engine 210. Once engine 210 has used the oil supplied via oil pump 2220 and oil supply line 2215 (i.e., the oil has become aerated and/or heated), the oil is returned to de-aeration oil tank 2210 via scavenge pump 2230.
Scavenge pump 2230 is configured to provide the aerated oil that has been used to lubricate and/or cool the various components in engine 210 to de-aeration oil tank 2210 via oil return line 2225, which may be in the form of tubes, channels, and/or other cavities in engine 210. The aerated oil is temporarily stored/held in de-aeration oil tank 2210 until the oil becomes substantially de-aerated, accumulates toward the bottom of de-aeration oil tank 2210, and the lubricating/cooling cycle repeats.
Secondary lubrication system 230 (which may be considered an emergency oil system) is configured to provide lubrication and/or cooling to the various moving components within engine 210 in predetermined situations (e.g., when primary lubrication system becomes damaged during combat, in the unlikely event that primary lubrication system 220 experiences a malfunction (e.g., low oil pressure and/or low oil quantity), at start-up of engine 210, at shut-down of engine 210, engine 210 operating at an extreme angle (e.g., attitude) that would impede normal oil supply and scavenge, the vehicle operating engine 210 performing a maneuver that impedes normal function of primary lubrication system 220, and/or the like situations). At least in the embodiment illustrated in
Pump 2320 may be any device and/or system capable of pumping the aerated oil in de-aeration oil tank 2210 to engine 210. That is, pump 2320 is configured to suck the aerated oil out of de-aeration tank 2210 and supply the aerated oil to engine 210. In one embodiment, pump 2320 is an oil pump. In another embodiment, pump 2320 is a jet pump.
Air pressure/flow generator 2340 may be any device and/or system capable of pressurizing de-aeration oil tank 2210. That is, air pressure/flow generator 2340 is configured to push the aerated oil out of de-aeration tank 2210 to engine 210.
To de-pressurize de-aeration oil tank 2210, vent 2350 can be opened, via valve 2337, to expel the pressure within de-aeration oil tank 2210. Although the embodiment illustrated in
Each sensor 2360 is configured to detect the oil pressure and/or oil level of engine 210 and/or primary lubrication system 220. One or more of sensors 2360 is/are configured to switch between operating primary lubrication system 220 and secondary lubrication system 230 depending on the one or more predetermined situations. That is, sensors(s) 2360 is/are configured to control air pressure/flow generator 2340, pump 2320, valve 2317, valve 2327, and/or valve 2337 in accordance with the operational status of primary lubrication system 220 and/or engine 210.
In one embodiment, secondary lubrication system 230 comprises a sensor 2360 configured to detect the oil pressure in engine 210 and/or primary lubrication system 220. In this embodiment, if sensor 2360 detects that the oil pressure in engine 210 and/or primary lubrication system 220 is below a predetermined pressure, sensor 2360 is configured to close valve 2327 and open valve 2317 such that oil stored within de-aeration oil tank 2210 is provided to engine 210 via oil supply line 2315. In addition, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON air pressure/flow generator 2340 to pressurize de-aeration oil tank 2210 such that the oil within de-aeration oil tank 2210 is “pushed” through oil supply line 2315. Alternatively or additionally, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON pump 2320 to suck the oil out of de-aeration oil tank 2210 and provide the oil to engine 210 via oil supply line 2315.
In another embodiment, secondary lubrication system 230 comprises a sensor 2360 configured to detect the oil level in engine 210 and/or primary lubrication system 220. In this embodiment, if sensor 2360 detects that the oil level in engine 210 and/or primary lubrication system 220 is below a predetermined level, sensor 2360 is configured to close valve 2327 and open valve 2317 such that oil stored within de-aeration oil tank 2210 is provided to engine 210 via oil supply line 2315. In addition, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON air pressure/flow generator 2340 to pressurize de-aeration oil tank 2210 such that the oil within de-aeration oil tank 2210 is “pushed” through oil supply line 2315. Alternatively or additionally, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON pump 2320 to suck the oil out of de-aeration oil tank 2210 and provide the oil to engine 210 via oil supply line 2315.
In yet another embodiment, secondary lubrication system 230 comprises one or more sensors 2360 configured to detect the oil pressure and oil level in engine 210 and/or primary lubrication system 220. In this embodiment, if the sensor(s) 2360 detect that the oil pressure and/or the oil level in engine 210 and/or primary lubrication system 220 is below a predetermined pressure and/or level, sensor 2360 is configured to close valve 2327 and open valve 2317 such that oil stored within de-aeration oil tank 2210 is provided to engine 210 via oil supply line 2315. In addition, sensor 2360 may close valve 2337 (if valve 2337 is open) and open air pressure/flow generator 2340 to pressurize de-aeration oil tank 2210 such that the oil within de-aeration oil tank 2210 is “pushed” through oil supply line 2315. Alternatively or additionally, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON pump 2320 to suck the oil out of de-aeration oil tank 2210 and provide the oil to engine 210 via oil supply line 2315.
In further embodiments of sensor 2360, sensor 2360 is configured to determine the operating status (e.g., start-up and/or shut-down) of engine 210. In one embodiment, if sensor 2360 detects that engine 210 is being started and/or shut down, sensor 2360 is configured to close valve 2327 and open valve 2317 such that oil stored within de-aeration oil tank 2210 is provided to engine 210 via oil supply line 2315. In addition, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON air pressure/flow generator 2340 to pressurize de-aeration oil tank 2210 such that the oil within de-aeration oil tank 2210 is “pushed” through oil supply line 2315. Alternatively or additionally, sensor 2360 may close valve 2337 (if valve 2337 is open) and turn ON pump 2320 to suck the oil out of de-aeration oil tank 2210 and provide the oil to engine 210 via oil supply line 2315.
During normal operation of engine 210, sensor 2360 is configured to close valve 2317 and open valve 2327 so that oil is provided to engine 210 via oil supply line 2215. During normal operation, air pressure/flow generator 2340 may be either turned ON or OFF and valve 2337 is closed or open, respectively, depending on if it is desirable to pressurize de-aeration oil tank 2210.
Engine 310 may be any engine or power plant capable of powering an aircraft (e.g., an airplane, a helicopter, an unmanned or manned aerial vehicle, etc.), a motor vehicle (e.g., a car, a truck, a military vehicle, etc.), a marine vessel (e.g., a boat, a ship, a submarine, etc.), and/or the like. That is, engine 310 typically includes various moving components (not shown) that need to be lubricated and/or cooled during operation of engine 310.
Primary lubrication system 320 is configured to provide lubrication and/or cooling to the various moving components within engine 310 using, for example, oil or some other type of lubricant/coolant. At least in the illustrated example of
De-aeration oil tank 3210 is configured to store/hold oil at various stages of aeration. That is, de-aeration oil tank 3210 is configured to store/hold aerated oil until the oil becomes substantially de-aerated. Once substantially de-aerated, the de-aerated oil is provided to primary oil tank 3275 via a valve 3327.
Primary oil tank 3275 is configured to store/hold de-aerated oil. Primary oil tank 3275 also includes an oil return line 3285 configured to return excess oil to de-aeration oil tank 3210 via a valve 3277 (e.g., a one-way valve), which is also configured to prevent aerated oil stored in de-aeration oil tank 3210 from entering primary oil tank 3275. When needed by engine 310, the aerated oil stored in primary oil tank 3275 is provided to engine 310 via oil pump 3220.
Oil pump 3220 is configured to provide the de-aerated oil in de-aeration oil tank 3210 to the various components of engine 310 that need to be lubricated and/or cooled via oil supply line 3215, which may be in the form of tubes, channels, and/or other cavities in engine 310. Once engine 310 has used the oil supplied via oil pump 3220 and oil supply line 3215 (i.e., the oil has become aerated and/or heated), the oil is returned to de-aeration oil tank 3210 via scavenge pump 3230.
Scavenge pump 3230 is configured to provide the aerated oil that has been used to lubricate and/or cool the various components in engine 310 to de-aeration oil tank 3210 via oil return line 3225, which may be in the form of tubes, channels, and/or other cavities in engine 310. The aerated oil is temporarily stored/held in de-aeration oil tank 3210 until the oil again becomes substantially de-aerated, accumulates toward the bottom of de-aeration oil tank 3210, and the lubricating/cooling cycle repeats.
Secondary lubrication system 330 (which may be considered an emergency oil system) is configured to provide lubrication and/or cooling to the various moving components within engine 310 in predetermined situations (e.g., when primary lubrication system becomes damaged during combat, in the unlikely event that primary lubrication system 320 experiences a malfunction (e.g., low oil pressure and/or low oil quantity), at start-up of engine 310, at shut-down of engine 310, and/or the like situations).
At least in the embodiment illustrated in
Pump 3320 may be any device and/or system capable of pumping the aerated oil in de-aeration oil tank 3210 to engine 310. That is, pump 3320 is configured to suck the aerated oil out of de-aeration tank 3210 and supply the aerated oil to engine 310. In one embodiment, pump 3320 is an oil pump. In another embodiment, pump 3320 is a jet pump. Valves 3327 and 3317 may be suction valves allowing pumps 3220 and 3320, respectively to take suction on de-aeration oil tank 3210.
Air pressure/flow generator 3340 may be any device and/or system capable of pressurizing de-aeration oil tank 3210. That is, air pressure/flow generator 3340 is configured to push the aerated oil out of de-aeration tank 3210 to engine 310.
To de-pressurize de-aeration oil tank 3210, vent 3350 can be opened, via valve 3337, to expel the pressure within de-aeration oil tank 3210. Although the embodiment illustrated in
Each sensor 3360 is configured to detect the oil pressure and/or oil level of engine 310 and/or primary lubrication system 320. One or more of sensors 3360 is/are configured to switch between operating primary lubrication system 320 and secondary lubrication system 330 depending on the one or more predetermined situations. That is, sensors(s) 3360 are configured to control air pressure/flow generator 3340, pump 3320, valve 3317, valve 3327, and/or valve 3337 in accordance with the operational status of primary lubrication system 320 and/or engine 310.
In one embodiment, secondary lubrication system 330 comprises a sensor 3360 configured to detect the oil pressure in engine 310 and/or primary lubrication system 320. In this embodiment, if sensor 3360 detects that the oil pressure in engine 310 and/or primary lubrication system 320 is below a predetermined pressure, sensor 3360 is configured to close valve 3327 and open valve 3317 such that oil stored within de-aeration oil tank 3210 is provided to engine 310 via oil supply line 3315. In addition, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON air pressure/flow generator 3340 to pressurize de-aeration oil tank 3210 such that the oil within de-aeration oil tank 3210 is “pushed” through oil supply line 3315. Alternatively or additionally, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON pump 3320 to suck the oil out of de-aeration oil tank 3210 and provide the oil to engine 310 via oil supply line 3315.
In another embodiment, secondary lubrication system 330 comprises a sensor 3360 configured to detect the oil level in engine 310 and/or primary lubrication system 320. In this embodiment, if sensor 3360 detects that the oil level in engine 310 and/or primary lubrication system 320 is below a predetermined level, sensor 3360 is configured to close valve 3327 and open valve 3317 such that oil stored within de-aeration oil tank 3210 is provided to engine 310 via oil supply line 3315. In addition, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON air pressure/flow generator 3340 to pressurize de-aeration oil tank 3210 such that the oil within de-aeration oil tank 3210 is “pushed” through oil supply line 3315. Alternatively or additionally, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON pump 3320 to suck the oil out of de-aeration oil tank 3210 and provide the oil to engine 310 via oil supply line 3315.
In yet another embodiment, secondary lubrication system 330 comprises one or more sensors 3360 configured to detect the oil pressure and oil level in engine 310 and/or primary lubrication system 320. In this embodiment, if the sensor(s) 3360 detect that the oil pressure and/or the oil level in engine 310 and/or primary lubrication system 320 is below a predetermined pressure and/or level, sensor 3360 is configured to close valve 3327 and open valve 3317 such that oil stored within de-aeration oil tank 3210 is provided to engine 310 via oil supply line 3315. In addition, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON air pressure/flow generator 3340 to pressurize de-aeration oil tank 3210 such that the oil within de-aeration oil tank 3210 is “pushed” through oil supply line 3315. Alternatively or additionally, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON pump 3320 to suck the oil out of de-aeration oil tank 3210 and provide the oil to engine 310 via oil supply line 3315.
In further embodiments of sensor 3360, sensor 3360 is configured to determine the operating status (e.g., start-up and/or shut-down) of engine 310. In one embodiment, if sensor 3360 detects that engine 310 is being started and/or shut down, sensor 3360 is configured to close valve 3327 and open valve 3317 such that oil stored within de-aeration oil tank 3210 is provided to engine 310 via oil supply line 3315. In addition, sensor 3360 may close valve 3337 (if valve 3337 is open) and turn ON air pressure/flow generator 3340 to pressurize de-aeration oil tank 3210 such that the oil within de-aeration oil tank 3210 is “pushed” through oil supply line 3315. Alternatively or additionally, sensor 3360 may close valve 3337 (if valve 2337 is open) and turn ON pump 3320 to suck the oil out of de-aeration oil tank 3210 and provide the oil to engine 310 via oil supply line 3315.
During normal operation of engine 310, sensor 3360 is configured to close valve 3317 and open valve 3327 so that oil is provided to engine 310 via oil supply line 3215. During normal operation, air pressure/flow generator 3340 may be either turned ON or OFF and valve 3337 is closed or open, respectively, depending on if it is desirable to pressurize de-aeration oil tank 3210.
Engine 410 may be any engine or power plant capable of powering an aircraft (e.g., an airplane, a helicopter, an unmanned or manned aerial vehicle, etc.), a motor vehicle (e.g., a car, a truck, a military vehicle, etc.), a marine vessel (e.g., a boat, a ship, a submarine, etc.), and/or the like. That is, engine 410 typically includes various moving components (not shown) that need to be lubricated and/or cooled during operation of engine 410.
Primary lubrication system 420 is configured to provide lubrication and/or cooling to the various moving components within engine 410 using, for example, oil or some other type of lubricant/coolant. At least in the illustrated example of
De-aeration oil tank 4210 is configured to store/hold oil at various stages of aeration. That is, de-aeration oil tank 4210 is configured to store/hold aerated oil until the oil becomes substantially de-aerated. Once substantially de-aerated, the de-aerated oil is provided to primary oil tank 4275 via a valve 4327 and a boost pump 4290, which is configured to pressurize primary oil tank 4275, along oil supply line 4215.
Primary oil tank 4275 is configured to store/hold de-aerated oil. Primary oil tank 4275 also includes an oil return line 4285 configured to return excess oil to de-aeration oil tank 4210 via a valve 4277 (e.g., a one-way valve), which is also configured to prevent aerated oil stored in de-aeration oil tank 4210 from entering primary oil tank 4275. When needed by engine 410, the aerated oil stored in primary oil tank 4275 is provided to engine 410 via oil pump 4220.
Oil pump 4220 is configured to provide the de-aerated oil in primary oil tank 4275 to the various components of engine 410 that need to be lubricated and/or cooled via oil supply line 4215, which may be in the form of tubes, channels, and/or other cavities in engine 410. Once engine 410 has used the oil supplied via oil pump 4220 and oil supply line 4215 (i.e., the oil has become aerated and/or heated), the oil is returned to de-aeration oil tank 4210 via scavenge pump 4230.
Scavenge pump 4230 is configured to provide the aerated oil that has been used to lubricate and/or cool the various components in engine 410 to de-aeration oil tank 4210 via oil return line 4225, which may be in the form of tubes, channels, and/or other cavities in engine 410. The aerated oil is temporarily stored/held in de-aeration oil tank 4210 until the oil again becomes substantially de-aerated, accumulates toward the bottom of de-aeration oil tank 4210, and the lubricating/cooling cycle repeats.
Secondary lubrication system 430 (which may be considered an emergency oil system) is configured to provide lubrication and/or cooling to the various moving components within engine 410 in predetermined situations (e.g., when primary lubrication system becomes damaged during combat, in the unlikely event that primary lubrication system 420 experiences a malfunction (e.g., low oil pressure and/or low oil quantity), at start-up of engine 410, at shut-down of engine 410, and/or the like situations). At least in the embodiment illustrated in
Pump 4320 may be any device and/or system capable of pumping the aerated oil in de-aeration oil tank 4210 to engine 410. That is, pump 4320 is configured to suck the aerated oil out of de-aeration tank 4210 and supply the aerated oil to engine 410. In one embodiment, pump 4320 is an oil pump. In another embodiment, pump 4320 is a jet pump.
Air pressure/flow generator 4340 may be any device and/or system capable of pressurizing de-aeration oil tank 4210. That is, air pressure/flow generator 4340 is configured to push the aerated oil out of de-aeration tank 4210 to engine 410.
To de-pressurize de-aeration oil tank 4210, vent 4350 can be opened, via valve 4337, to expel the pressure within de-aeration oil tank 4210. Although the embodiment illustrated in
Each sensor 4360 is configured to detect the oil pressure and/or oil level of engine 410 and/or primary lubrication system 420. One or more of sensors 4360 is/are configured to switch between operating primary lubrication system 420 and secondary lubrication system 430 depending on the one or more predetermined situations. That is, sensors(s) 4360 are configured to control air pressure/flow generator 4340, pump 4320, valve 4317, valve 4327, and/or valve 4337 in accordance with the operational status of primary lubrication system 420 and/or engine 410.
In one embodiment, secondary lubrication system 430 comprises a sensor 4360 configured to detect the oil pressure in engine 410 and/or primary lubrication system 420. In this embodiment, if sensor 4360 detects that the oil pressure in engine 410 and/or primary lubrication system 420 is below a predetermined pressure, sensor 4360 is configured to close valve 4327 and open valve 4317 such that oil stored within de-aeration oil tank 4210 is provided to engine 410 via oil supply line 4315. In addition, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON air pressure/flow generator 4340 to pressurize de-aeration oil tank 4210 such that the oil within de-aeration oil tank 4210 is “pushed” through oil supply line 4315. Alternatively or additionally, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON pump 4320 to suck the oil out of de-aeration oil tank 4210 and provide the oil to engine 410 via oil supply line 4315.
In another embodiment, secondary lubrication system 430 comprises a sensor 4360 configured to detect the oil level in engine 410 and/or primary lubrication system 420. In this embodiment, if sensor 4360 detects that the oil level in engine 410 and/or primary lubrication system 420 is below a predetermined level, sensor 4360 is configured to close valve 4327 and open valve 4317 such that oil stored within de-aeration oil tank 4210 is provided to engine 410 via oil supply line 4315. In addition, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON air pressure/flow generator 4340 to pressurize de-aeration oil tank 4210 such that the oil within de-aeration oil tank 4210 is “pushed” through oil supply line 4315. Alternatively or additionally, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON pump 4320 to suck the oil out of de-aeration oil tank 4210 and provide the oil to engine 410 via oil supply line 4315.
In yet another embodiment, secondary lubrication system 430 comprises one or more sensors 4360 configured to detect the oil pressure and oil level in engine 410 and/or primary lubrication system 420. In this embodiment, if the sensor(s) 4360 detect that the oil pressure and/or the oil level in engine 410 and/or primary lubrication system 420 is below a predetermined pressure and/or level, sensor 4360 is configured to close valve 4327 and open valve 4317 such that oil stored within de-aeration oil tank 4210 is provided to engine 410 via oil supply line 4315. In addition, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON air pressure/flow generator 4340 to pressurize de-aeration oil tank 4210 such that the oil within de-aeration oil tank 4210 is “pushed” through oil supply line 4315. Alternatively or additionally, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON pump 4320 to suck the oil out of de-aeration oil tank 4210 and provide the oil to engine 410 via oil supply line 4315.
In further embodiments of sensor 4360, sensor 4360 is configured to determine the operating status (e.g., start-up and/or shut-down) of engine 410. In one embodiment, if sensor 4360 detects that engine 410 is being started and/or shut down, sensor 4360 is configured to close valve 4327 and open valve 4317 such that oil stored within de-aeration oil tank 4210 is provided to engine 410 via oil supply line 4315. In addition, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON air pressure/flow generator 4340 to pressurize de-aeration oil tank 4210 such that the oil within de-aeration oil tank 4210 is “pushed” through oil supply line 4315. Alternatively or additionally, sensor 4360 may close valve 4337 (if valve 4337 is open) and turn ON pump 4320 to suck the oil out of de-aeration oil tank 4210 and provide the oil to engine 410 via oil supply line 4315.
During normal operation of engine 410, sensor 4360 is configured to close valve 4317 and open valve 4327 so that oil is provided to engine 410 via oil supply line 4215. During normal operation, air pressure/flow generator 4340 may be either turned ON or OFF and valve 4337 is closed or open, respectively, depending on if it is desirable to pressurize de-aeration oil tank 4210.
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims and their legal equivalents.
The U.S. Government has a paid-up license in this invention and the right in limited circumstances to require the patent owner to license others on reasonable terms as provided by the terms of Contract No. W911W6-08-2-0001 awarded by the United States Army.
Number | Name | Date | Kind |
---|---|---|---|
3779345 | Barnes et al. | Dec 1973 | A |
4002224 | Easter | Jan 1977 | A |
4153141 | Methlie | May 1979 | A |
4284174 | Salvana et al. | Aug 1981 | A |
4373421 | Camboulives et al. | Feb 1983 | A |
4681189 | Krisiloff | Jul 1987 | A |
4888947 | Thompson | Dec 1989 | A |
5018601 | Waddington et al. | May 1991 | A |
5196746 | McCabria | Mar 1993 | A |
5316737 | Skelley et al. | May 1994 | A |
5526783 | Ito et al. | Jun 1996 | A |
5526789 | Stein et al. | Jun 1996 | A |
5568842 | Otani | Oct 1996 | A |
5660358 | Grafwallner et al. | Aug 1997 | A |
5829401 | Masuda | Nov 1998 | A |
6113676 | Kumpulainen | Sep 2000 | A |
6227221 | Schmitz | May 2001 | B1 |
6941922 | Williams et al. | Sep 2005 | B2 |
7080620 | Aronsson et al. | Jul 2006 | B2 |
7174997 | Sheridan | Feb 2007 | B2 |
7387189 | James et al. | Jun 2008 | B2 |
20020007736 | Hearn et al. | Jan 2002 | A1 |
20050034924 | James et al. | Feb 2005 | A1 |
20060102133 | Callan | May 2006 | A1 |
20080116009 | Sheridan et al. | May 2008 | A1 |
20080196974 | Galivel | Aug 2008 | A1 |
Number | Date | Country | |
---|---|---|---|
20100229823 A1 | Sep 2010 | US |