Small diesel engine-load set

Abstract

An engine-generator set with a single-cylinder diesel engine and an electrical generator with a rotor secured to the engine crankshaft. The rotor is cantilevered on an end of the crankshaft. The engine has an electrically activatable fuel injector connected to a continuously pressurized fuel supply, such as in a common rail injection system. The engine exhaust passes through a catalyst bed. In a marine version, the catalyst bed is disposed within an injection elbow.

Claims

1. An engine-load set comprising: a diesel engine with a rotatable crankshaft; and a rotor secured to the crankshaft for rotation, the rotor cantilevered on an end of the crankshaft; wherein the engine is a single-cylinder engine and has an electrically activatable fuel injector connected to a continuously pressurized fuel supply; and wherein the engine has an exhaust system arranged to receive a flow of exhaust from the single cylinder.

2. The engine-load set of claim 1, wherein the engine is a marine engine.

3. The engine-load set of claim 1, wherein the engine defines a cooling passage in hydraulic communication with both a raw water inlet and a raw water outlet into the exhaust system of the engine.

4. The engine-load set of claim 3, wherein the exhaust system contains a catalyst, and wherein the cooling passage is also in hydraulic communication with a cooling jacket extending at least partially about the catalyst.

5. The engine-load set of claim 1, wherein the engine is air-cooled.

6. The engine-load set of claim 1, wherein the engine-load set is mounted on a vehicle and configured to produce electrical power for powering a cooling system of the vehicle.

7. The engine-load set of claim 6, wherein the engine is mounted with its crankshaft extending horizontally.

8. The engine-load set of claim 1, wherein the generator is a variable-speed generator.

9. The engine-load set of claim 1, wherein the generator is a permanent magnet generator.

10. The engine-load set of claim 1, further comprising a sound-attenuating enclosure surrounding the engine and the generator.

11. The engine-load set of claim 10, wherein the engine is mounted to the sound-attenuating enclosure by a vibration isolator.

12. The engine-load set of claim 1, wherein the exhaust system is arranged to pass the received exhaust through a catalyst.

13. The engine-load set of claim 12, further comprising an oxygen sensor arranged to be exposed to the flow of exhaust and configured to be responsive to oxygen content in the flow.

14. An engine-generator set comprising: a diesel engine with a rotatable crankshaft; and an electrical generator with a rotor secured to the crankshaft for rotation, the rotor cantilevered on an end of the crankshaft; wherein the engine has an electrically activatable fuel injector connected to a continuously pressurized fuel supply; and wherein the engine is configured for liquid cooling; and wherein the engine exhaust system is arranged to receive a flow of exhaust and to pass the received exhaust through a catalyst.

15. The engine-generator set of claim 14, further comprising an oxygen sensor arranged to be exposed to the flow of exhaust and configured to be responsive to oxygen content in the flow.

16. The engine-generator set of claim 14, wherein the engine is air-cooled.

17. The engine-generator set of any of claim 14, wherein the engine-generator set is mounted on a boat and configured to produce electrical power for powering a cooling system of the boat.

18. The engine-generator set of claim 17, wherein the engine is mounted with its crankshaft extending horizontally.

19. The engine-generator set of claim 14, wherein the generator is a variable-speed generator.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is an illustration of a truck and a boat, each including an auxiliary engine-generator set for powering onboard systems.

(2) FIG. 2 is a side cutaway view of an enclosed engine-generator set, with the generator mounted to the engine on a side opposite the flywheel.

(3) FIG. 3 is a perspective view of an engine-generator set, with the generator mounted to the engine at the flywheel end of the crankshaft.

(4) FIG. 4 is a schematic representation of a cross-section of a permanent magnet generator, coupled to an inverter/rectifier and battery.

(5) FIG. 5 illustrates a dry exhaust, such as on a road vehicle.

(6) FIG. 6 illustrates a wet exhaust, such as on a boat.

(7) Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

(8) Referring first to FIG. 1, an on-road vehicle 6 and a boat 8 are each shown with an enclosed diesel engine-load set in the form of an engine-generator set 10 configured to consume diesel fuel to produce electrical power that can be provided directly to on-board systems such as HVAC equipment, or stored in one or more on-board batteries (not shown) for later use. Fuel may be provided from a tank that also feeds a propulsion engine, or from a separate tank. The vehicle-mounted and boat-mounted engine-generator sets meet the additional federal guidelines and requirements for on-road and marine use, respectively. They are each preferably enclosed in a sound-dampening enclosure 12, as discussed below with respect to FIG. 2.

(9) Referring to FIG. 2, enclosure 12 completely surrounds the engine 14 and generator 16 of the engine-generator set, other than for fuel and combustion air inlets, an exhaust outlet, cooling water inlet and outlet, and electrical cables (not shown). The enclosure has a base and a removable cover, for accessing the engine and generator for service. The entire unit, including the enclosure, preferably has a volume of less than about one cubic meter.

(10) The engine-generator set is mounted within the enclosure on vibration isolators, and the enclosure itself may be mounted on isolators, to minimize vibration coupling to the boat or vehicle.

(11) The engine 14 is preferably a one-cylinder diesel engine, such as a Model 178/186 available from various sources including Chang Chai, or a Model L70/L100 engine from Yanmar. It includes at least one solenoid-actuated fuel injector, electronically controlled by an engine controller (not shown) to inject timed bursts of fuel into the single cylinder, preferably multiple bursts per cycle from a fuel line held at a pressure of 10 to 20 ksi (70 to 140 MPa). The injector is controlled such that the timing and amount of fuel are optimal for minimizing emissions under sensed power output and speed conditions. The engine-generator set should be able to produce 5 kW of continuous AC power at 50 or 60 Hz and 120 or 240 volts, meeting U.S. EPA and European emissions standards for marine and vehicle use. The engine may be configured for air cooling or liquid (e.g., water) cooling. If air-cooled, the enclosure will provide for a cooling air inlet and outlet. If the engine is cooled by a closed loop liquid circuit, the enclosure will provide for a coolant inlet and outlet connected to an external radiator. If the engine is marinized and cooled by raw water, the enclosure will provide for a seawater inlet.

(12) The engine is started by an electric starting motor. In some cases the generator is also configured to serve as the starting motor. Alternatively, a separate starting motor 18 may be mounted to drive the crankshaft of the engine, such as through a flywheel. In this example, the generator 16 is mounted at an end of the crankshaft opposite the flywheel, which is enclosed in a shroud 20. The generator rotor 22 is rigidly coupled to the crankshaft and cantilevered, such that there is no bearing supporting the rotor other than through the crankshaft.

(13) Alternatively, the generator can be mounted on what would be the flywheel end of the crankshaft, as shown in FIG. 3. In this configuration, the generator rotor 22 is again rigidly coupled to the crankshaft and cantilevered. That is, the crankshaft 28 and the generator rotor are together supported by rotation only by bearings supported by the engine block 26. In this illustrated example, a flywheel 24 is also secured to the crankshaft and rotor, and engaged by starter motor 18 to start the engine. Alternatively, the generator rotor 22 may have sufficient inertia to serve as the engine flywheel, and starting can be accomplished by driving the generator electrically (such as by providing a separate starting winding in the generator). In the configuration of FIG. 3, the opposite end of crankshaft 28 remains available to drive another component or system. In both illustrated configurations, the cylinder bore is arranged vertically to provide a small engine footprint.

(14) Referring next to FIG. 4, generator 16 is preferably a high efficiency, permanent magnet generator (PMG). The stator coils 30 send electrical power to an inverter/rectifier 32 coupled to a battery 34 for storage and to an AC main circuit 36 from which onboard systems may be powered. Inverter/rectifier 32 works at variable generator speeds, allowing the asynchronous generator to run at lower speeds at lower loads, for lower overall noise. The engine-generator is electronically governed in order to provide rapid speed and fuel fluctuations in response to rapid load changes. Preferably, the generator speed is controlled in accordance with a table of discrete speed steps, to avoid continuous noise changes from minor speed fluctuations. While the generator is illustrated as elongated, for many applications the generator may be shorter than the diameter of the stator, providing a low overall system footprint and lower bearing loads. The rotor 22 carries rare earth permanent magnets for high energy density.

(15) Alternatively, the generator may be a synchronous PMG operating at a constant speed and providing output power at the desired frequency.

(16) Referring next to FIG. 5, in a road vehicle application the cylinder exhaust is routed past an oxygen sensor 40 and through a catalyst bed 42 that oxidizes unwanted exhaust components. This engine is shown to be liquid-cooled, with cooling channels 44 defined in the engine block for removing heat to a remote radiator.

(17) Referring to FIG. 6, in a marine application the cylinder exhaust may be routed through a catalyst bed 42 within an injection elbow 46, such that downstream of the catalyst bed the exhaust flow merges with a flow of raw water 48 from a water inlet 50, and the wet exhaust is routed to an exit, either above or below the water line. An oxygen sensor may also be included, as in the above-described road vehicle application, upstream of the injection elbow.

(18) While a number of examples have been described for illustration purposes, the foregoing description is not intended to limit the scope of the invention, which is defined by the scope of the appended claims. There are and will be other examples and modifications within the scope of the following claims.