IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
|
출원번호 |
US-0677404
(1976-04-15)
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발명자
/ 주소 |
- Firey Joseph Carl (P. O. Box 254
- Northgate Station Seattle WA 98125)
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인용정보 |
피인용 횟수 :
14 인용 특허 :
0 |
초록
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The gasoline engine torque regulator described herein provides means of reducing the quantities of harmful oxides of nitrogen emitted via the exhaust of a four stroke cycle gasoline engine and also of increasing the efficiency of the engine at part load, with an engine torque characteristic either a
The gasoline engine torque regulator described herein provides means of reducing the quantities of harmful oxides of nitrogen emitted via the exhaust of a four stroke cycle gasoline engine and also of increasing the efficiency of the engine at part load, with an engine torque characteristic either approximately constant with engine speed or alternatively controllably decreasing with increasing engine speed. These beneficial objects are achieved by adjustably delaying the closing of the engine intake valve as a means of controlling the engine torque, the opening of the intake valve remaining fixed. This manner of intake valve opening and closing can be achieved by adding to the conventional intake valve operating mechanism a dashpot device with a check valve and a positive displacement flow regulator. The check valve allows ready flow of the dashpot fluid between dashpot chambers when the intake valve is being opened but closes and forces fluid to flow oppositely, during intake valve closing, at least partially via the positive displacement flow regulator which proportions the flow and hence the rate of valve closure to the speed of the engine. With intake valve closing thereby delayed, a portion of the air-fuel mixture, drawn into the engine cylinder during the intake stroke, is pushed back into the intake manifold during the compression stroke. As a result less air-fuel mixture remains in the engine cylinder and the engine torque is reduced, the extent of such torque reduction increasing as the intake valve closing is longer delayed. The engine compression ratio is reduced at reduced torque and, in consequence, gas temperatures during compression, combustion and expansion are reduced, producing a beneficial decrease in the quantities of oxides of nitrogen formed and subsequently emitted. Part load efficiency of the engine is increased because pumping work is essentially eliminated.
대표청구항
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The combination of a four stroke cycle gasoline engine, complete with engine intake valves, intake valve closing springs, intake valve operating cams and linkage, and additionally fitted with a dashpot connecting between each such engine intake valve and the frame of the engine, wherein the improvem
The combination of a four stroke cycle gasoline engine, complete with engine intake valves, intake valve closing springs, intake valve operating cams and linkage, and additionally fitted with a dashpot connecting between each such engine intake valve and the frame of the engine, wherein the improvement comprises connecting the two chambers of each such dashpot together via a fixed stroke, positive displacement flow regulator; said fixed stroke, positive displacement, flow regulator comprising a fixed port element, a rotating port element and drive, a free piston element, and a port regulator element with torque control linkage; said fixed port element being secured to the engine frame and containing a cavity, within which the rotating port element rotates, and having two groups of fixed ports; one group of fixed ports; the pressure fixed ports, being connected individually to the port regulator element whose other connection is via a portion of the control passage to one chamber of the dashpot, these pressure fixed ports connecting into the cavity in two sets of pressure fixed ports, each such set being coplanar in a plane at right angles to the axis of rotation of the rotating port element, the plane containing the one set of pressure fixed ports being displaced axially along said axis of rotation from the plane containing the other set of pressure fixed ports by a distance sufficient for sealing therebetween, the pressure fixed ports of each such set being angularly displaced relative to each other about said axis of rotation, the number of such pressure fixed ports in each set of the two sets being an integral odd number; the other group of fixed ports, the discharge fixed ports, being connected together and jointly connecting via the other portion of the control passage to the opposite chamber of the dashpot these discharge fixed ports connecting into the cavity in two sets of discharge fixed ports, each such set being coplanar in a plane at right angles to the axis of rotation of the rotating port element, these two planes containing these two sets of discharge fixed ports being coincident with the two planes containing the two sets of pressure fixed ports, the discharge fixed ports of each such set being angularly displaced relative to each other and each such discharge fixed port being displaced 180°from one of the coplanar pressure fixed ports about said axis of rotation, the number of such discharge fixed ports in each set of the two sets being equal to the number of pressure fixed ports with which they are coplanar, the pressure fixed ports of one coplanar set of pressure and discharge fixed ports being angularly displaced from the discharge fixed ports of the other coplanar set of pressure and discharge fixed ports by the displacement angle between the rotating ports as described hereinafter; said rotating port element being positively rotated, within the cavity in the fixed port element, as by gears or chains, from an engine shaft such as the crankshaft or camshaft, said rotating port element being closely and sealably fitted to the cavity in the fixed port elEment; said rotating port element being fitted with two passages, each such passage being fitted with two ports at its ends, one such port of one such passage indexing with and being always coplanar with one set of coplanar pressure and discharge fixed ports in the fixed port element the other port of this same passage connecting always to one end of the free piston element as described hereinafter, one such port of the other passage indexing with and being always coplanar with the other set of coplanar pressure and discharge fixed ports in the fixed port element the other port of this latter passage connecting always to the other end of the free piston element, said two rotating ports which index with and are coplanar with the pressure and discharge fixed ports being angularly displaced from one another about the axis of rotation of the rotating port element by the displacement angle which can have any value between zero and 180°; said rotating port element being axially held in alignment within the cavity in the fixed port element so that the rotating ports index with and remain coplanar with the sets of pressure fixed ports and discharge fixed ports; said free piston element being a free piston and closed ended cylinder with the free piston fitted closely and moveably within the cylinder and being free to move within said cylinder, one end of said cylinder connecting always into one passage in the rotating port element and the other end of said cylinder connecting always into the other passage in the rotating port element; the ends of said cylinder being closed; said port regulator element comprising a fixed port housing secured to the engine frame and a moveable regulator bar secured to the engine torque control linkage; said fixed port housing containing an open ended cylindrical cavity with cavity ports giving access to and distributed along a portion of the length of said cylindrical cavity, the number of such cavity ports being equal to one more than the number of pressure ports in the fixed port element and each such pressure port being connected individually to one such cavity port, the one extra cavity port not connected to a pressure port being connected via a portion of the control passage to one chamber of the dashpot and being coplanar with that one cavity port which does connect to a pressure port and is never closed by the moveable regulator bar in a plane at right angles to the centerline axis of the cylindrical cavity in the fixed port housing; said moveable regulator bar fitting closely, sealably and axially moveably within the cylindrical cavity in the fixed port housing and having two axial motion stops and a tapered recessed portion of its length between seals, the length of said tapered recessed portion being somewhat longer than the length of that portion of the cylindrical cavity containing the cavity ports, one of the axial motion stops being positioned on the moveable regulator bar so that when the bar is pushed against this stop the tapered recessed portion aligns with that portion of the cylindrical cavity containing the cavity ports and all cavity ports are open, the other axial motion stop being positioned on the moveable regulator bar so that when the bar is pushed against this stop the tapered recessed portion aligns and opens only with that pair of cavity ports which are coplanar and includes the one extra cavity port not connected to a pressure port, said moveable regulator bar being axially moveable to any position between the two positions set by the two axial motion stops via a torque control linkage connected to said moveable regulator bar, such axial motion closing off or opening up cavity ports to the tapered recessed portion of the moveable regulator bar; the displacement volume of one full stroke of the dashpot, VD, the displacement volume of one full stroke of the free piston, VP, the total number of pressure fixed ports in the fixed port element, n, the revolutions per minute of the rotating port element, NR, the revolutions per minute of the engine, NE, are necessarily related to one another and to the minimum intake valve closing angle, AM, in crankshaft radians, according to the following equations; (VP) (n) (NR) (AM) =(6.283) (VD) (NE) (VP) (n) (NR/NE) (AM) =(6.283) (VD) wherein the speed ratio, NR/NE, is determined by the positive drive mechanism driving the rotating port element from the engine shaft; and related to the maximum intake valve closing angle, AX, in crankshaft radians, according to the following equations; (VP)(NR/NE)(AX) =6.283 VD (VP)n(NR/NE) (AM) =6.283 VD (AX) (AX) =n(AM) wherein the minimum intake valve closing angle, AM, is at least as samll as the intake valve closing angle in crankshaft radians of the intake cam on the engine camshaft, AC, and is preferably less than AC up to as small as one half of AC; wherein the maximum intake valve closing angle, AX, is equal to the minimum intake valve closing angle, AM, plus 3 radians minus the maximum engine ignition spark advance in crankshaft radians before piston top dead center; on multicylinder gasoline engines the several moveable regulator bars of the several fixed stroke, positive displacement, flow regulators being connected to the torque control linkage with equal cavity port opening.
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