Supercharge control apparatus and supercharge control method for supercharged internal combustion engine
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02B-033/44
F02B-037/00
F02B-037/12
F02B-037/24
F02D-023/00
출원번호
US-0021665
(2004-12-23)
우선권정보
JP-2003-428208(2003-12-24)
발명자
/ 주소
Takahashi,Yoshiyuki
Narita,Yuji
Suzuki,Hisanobu
출원인 / 주소
Kabushiki Kaisha Toyota Jidoshokki
Toyota Jidosha Kabushiki Kaisha
대리인 / 주소
Woodcock Washburn LLP
인용정보
피인용 횟수 :
9인용 특허 :
12
초록▼
A detecting device detects boost condition of each of a plurality of superchargers. The detecting device includes at least two of a pressure ratio detecting unit, which detects the ratio of the pressure downstream each supercharger to the pressure upstream each supercharger; an air flow rate detecti
A detecting device detects boost condition of each of a plurality of superchargers. The detecting device includes at least two of a pressure ratio detecting unit, which detects the ratio of the pressure downstream each supercharger to the pressure upstream each supercharger; an air flow rate detecting unit, which detects the flow rate of air passing through each supercharger; and a rotational speed detecting unit, which detects the rotational speed of each supercharger. When it is determined that the boost condition of only part of the superchargers is within the surging area, a control unit increases the air flow rate of the supercharger, the boost condition of which is determined to be in the surging area. Therefore, the limitation of the flow rate of air supply is raised.
대표청구항▼
The invention claimed is: 1. A supercharge control apparatus for an internal combustion engine, wherein the internal combustion engine includes a plurality of superchargers, and air fed from the superchargers are combined and supplied to the internal combustion engine, the apparatus comprising: a d
The invention claimed is: 1. A supercharge control apparatus for an internal combustion engine, wherein the internal combustion engine includes a plurality of superchargers, and air fed from the superchargers are combined and supplied to the internal combustion engine, the apparatus comprising: a detecting device for detecting boost condition of each of the superchargers, the detecting device including at least two of a pressure ratio detecting unit, which detects the ratio of the pressure downstream each supercharger to the pressure upstream each supercharger, an air flow rate detecting unit, which detects the flow rate of air passing through each supercharger, and a rotational speed detecting unit, which detects the rotational speed of each supercharger; a determining unit, which determines whether the boost condition is within a predetermined surging area; and a control unit, when it is determined that the boost condition of only part of the superchargers is within the surging area, the control unit increases the air flow rate of the supercharger, the boost condition of which is determined to be in the surging area, wherein the engine includes intake passages each of which corresponds to one of the superchargers, the pressure ration detecting unit comprising: an atmospheric pressure detecting unit, which detects the atmospheric pressure; a pressure detecting unit, which detects the pressure in the intake passages downstream the superchargers; and a pressure ratio computing unit, which computes the ratio of the pressure downstream the superchargers to the atmospheric pressure. 2. The control apparatus according to claim 1, wherein the boost condition is represented by a coordinate in a two-dimensional coordinate system defined by the pressure ratio and the air flow rate, the coordinate system includes a surging line, which divides the coordinate system into a surging area and a non-surging area, and the surging line is set such that under the same pressure ratio, the value of the air flow rate in the surging area is smaller than that in the non-surging area, and under the same air flow rate, the value of the pressure ratio included in the surging area is greater than that in the non-surging area. 3. The control apparatus according to claim 1, wherein the detecting device includes the pressure ratio detecting unit and the air flow rate detecting unit, and the boost condition is represented by the pressure ratio and the air flow rate. 4. The control apparatus according to claim 1, wherein, when it is determined that the boost condition of only part of the superchargers is within the surging area, the control unit decreases the air flow rate of the supercharger, the boost condition of which is determined to be not in the surging area. 5. The control apparatus according to claim 1, wherein the superchargers are operated by exhaust gas flow, the superchargers are variable nozzle type having a vane the opening degree of which is variable, and the control unit increases the air flow rate of the supercharger by decreasing the opening degree of the vane and decreases the air flow rate of the supercharger by increasing the opening degree of the vane. 6. A supercharge control apparatus for an internal combustion engine, wherein the internal combustion engine includes a plurality of superchargers, and air fed from the superchargers are combined and supplied to the internal combustion engine, the apparatus comprising: a detecting device for detecting boost condition of each of the superchargers, the detecting device including at least two of a pressure ratio detecting unit, which detects the ratio of the pressure downstream the supercharger to the pressure upstream the supercharger, an air flow rate detecting unit, which detects the flow rate of air passing through each supercharger, and a rotational speed detecting unit, which detects the rotational speed of each supercharger; a determining unit, which determines whether the boost condition is within a predetermined surging area; and a control unit, when it is determined that the boost condition of only part of the superchargers is within the surging area, the control unit decreases the air flow rate of the supercharger other than the part of the superchargers the boost condition of which is determined to be in the surging area, wherein the engine includes intake passages each of which corresponds to one of the superchargers, the pressure ratio detecting unit comprising: an atmospheric pressure detecting unit, which detects the atmospheric pressure; a pressure detecting unit, which detects the pressure in the intake passages downstream the superchargers; and a pressure ratio computing unit, which detects the ratio of the pressure downstream the superchargers to the atmospheric pressure. 7. The control apparatus according to claim 6, wherein the boost condition is represented by a coordinate in a two-dimensional coordinate system defined by the pressure ratio and the air flow rate, the coordinate system includes a surging line, which divides the coordinate system into a surging area and a non-surging area, and the surging line is set such that under the same pressure ratio, the value of the air flow rate in the surging area is smaller than that in the non-surging area, and under the same air flow rate, the value of the pressure ratio included in the surging area is greater than that in the non-surging area. 8. The control apparatus according to claim 6, wherein the detecting device includes the pressure ratio detecting unit and the air flow rate detecting unit, and the boost condition is represented by the pressure ratio and the air flow rate. 9. The control apparatus according to claim 6, wherein the superchargers are operated by exhaust gas flow, the superchargers are variable nozzle type having a vane the opening degree of which is variable, and the control unit increases the air flow rate of the supercharger by decreasing the opening degree of the vane and decreases the air flow rate of the supercharger by increasing the opening degree of the vane. 10. A supercharge control method for an internal combustion engine, which includes a plurality of superchargers, the method comprising: combining air fed from the superchargers and supplying the air to the internal combustion engine; detecting a parameter representing boost condition of each of the superchargers, wherein the parameter includes at least two of the ratio of the pressure downstream each supercharger to the pressure upstream each supercharger, the flow rate of air passing through each supercharger, and the rotational speed of each supercharger; determining whether the boost condition is within a predetermined surging area; and when it is determined that the boost condition of only part of the superchargers is within the surging area, increasing the air flow rate of the supercharger, the boost condition of which is determined to be in the surging area, the method further comprising: detecting the atmospheric pressure; detecting the pressure at a portion downstream each of the supercharger; and computing the ratio of the pressure downstream each supercharger to the atmospheric pressure. 11. The control method according to claim 10, wherein the parameter includes the pressure ratio and the air flow rate, the control method further comprising: obtaining the boost condition in accordance with the pressure ratio and the air flow rate. 12. The control method according to claim 10, further comprising, when it is determined that the boost condition of only part of the superchargers is within the surging area, decreasing the air flow rate of the supercharger, the boost condition of which is determined to be not in the surging area. 13. The control method according to claim 10, wherein the superchargers are variable nozzle type having a vane the opening degree of which is variable, the control method further comprising: operating the superchargers by exhaust gas flow; and increasing the air flow rate of the supercharger by decreasing the opening degree of the vane. 14. A supercharge control method for an internal combustion engine, which includes a plurality of superchargers, the method comprising: combining air fed from the superchargers and supplying the air to the internal combustion engine; detecting a parameter representing boost condition of each of the superchargers, wherein the parameter includes at least two of the ratio of the pressure downstream each supercharger to the pressure upstream each supercharger, the flow rate of air passing through each supercharger, and the rotational speed of each supercharger; determining whether the boost condition is within a predetermined surging area; and when it is determined that the boost condition of only part of the superchargers is within the surging area, decreasing the air flow rate of the supercharger other than the part of the superchargers the boost condition of which is determined to be in the surging area, the method further comprising: detecting the atmospheric pressure; detecting the pressure at a portion downstream each of the superchargers; and computing the ratio of the pressure downstream each supercharger to the atmospheric pressure. 15. The control method according to claim 14, wherein the parameter includes the pressure ratio and the air flow rate, the control method further comprising: obtaining the boost condition in accordance with the pressure ratio and the air flow rate. 16. The control method according to claim 14, wherein the superchargers are variable nozzle type having a vane the opening degree of which is variable, the control method further comprising: operating the superchargers by exhaust gas flow; and decreasing the air flow rate of the supercharger by increasing the opening degree of the vane.
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Bonitz Jrg (Mhlacker DEX) Rohde Siegfried (Oberriexingen DEX) Miller Bernhard (Stuttgart DEX) Knzel Walter (Ludwigsburg DEX), Process and device for boost control.
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