The invention relates to a method for operating a reciprocating-piston internal combustion engine having internal exhaust gas energy recuperation. The invention further relates to a reciprocating-piston internal combustion engine having internal exhaust gas energy recuperation.
A reciprocating-piston internal combustion engine having internal exhaust gas energy recuperation is known from U.S. Pat. No. 4,790,284, in which an overall plate-shaped recuperator is reciprocally movable in the cylinders of the internal combustion engine between the cylinder head and each of the respective pistons. The recuperator fills the entire cylindrical cross-section and is movable by a shaft that passes through the cylinder head in a sealed manner. Fluid located in the cylinder can move from the space above the recuperator into the space below the recuperator only by flowing through the recuperator. During an intake stroke, the recuperator abuts on the upper side of the piston and follows the piston movement from the TDC to the BDC. During a first part of the compression, the recuperator continues to move together with the piston from the BDC towards the TDC while in abutment on the upper side of the piston and clearly moves away from the piston into abutment on the cylinder head before the piston reaches its TDC. As a result, the cylinder charge that flows through the recuperator is warmed by the recuperator. Then, fuel is injected into the warmed charge, which combusts by spontaneous ignition, so that the piston moves to its BDC, wherein the recuperator remains in abutment on the cylinder head. When the piston reaches its BDC and then moves towards the TDC to exhaust the charge, the recuperator moves towards the piston, so that the combusted charge flows through the recuperator and heats it. Then, the recuperator moves with the piston to its TDC, so that the charge located between the recuperator and the cylinder head is exhausted through the open exhaust valve.
The object underlying the invention is to provide a method for operating an internal combustion engine having internal exhaust gas energy recuperation, as well as an internal combustion engine, which operate(s) with improved efficiency with a simple flow-through-ability and/or simple construction.
The part of the inventive object relating to the method is achieved by the features of claim 1.
Dependent claims 2 to 5 are directed to advantageous embodiments of the inventive method.
Claim 6 denotes the construction of an internal combustion engine for achieving the part of the inventive object in this regard.
The inventive internal combustion engine is further developed in an advantageous manner with the features of claims 7-10.
An aspect of the invention is that the cylinder head recuperator does not completely fill the cross-section of the cylinder, so that the intake valve can be opened when the recuperator is located in its top dead center and the fresh charge flows into the cylinder adjacent to the cylinder head recuperator. During the compression stroke, the cylinder head recuperator moves from its top dead center into a bottom dead center in a stroke, which is smaller than the stroke of the piston, and moves back into its top dead center at the end of the compression stroke. During the exhaust stroke with the exhaust valve open, the cylinder head recuperator moves away from its top dead center, and moves back to its top dead center upon closing of the exhaust valve. In spite of the smaller stroke of the cylinder head recuperator as compared to the piston stroke, a higher efficiency is achieved with respect to the utilization of the thermal energy contained in the exhaust gas.
The invention will be explained in an exemplary manner in the following with the assistance of schematic drawings and with further details.
In
According to
The cylinder 10 is closed from above by a front wall 14, which is formed by a cylinder head and in which an intake channel 18 leading into the power chamber 16 of the cylinder 10 and an exhaust channel 20 leading out of the power chamber 16 are formed.
In the intake opening, in which the intake channel 18 opens into the power chamber 16, an intake valve 22 operates that is actuated by an intake cam 24. In the exhaust opening, in which the exhaust channel 20 emanates from the power chamber 16, an exhaust valve 26 operates that is actuated by an exhaust cam 28.
In the construction of an internal combustion engine having direct fuel injection, an injector nozzle 30 is disposed in the front wall 14, by which fuel is injected into the power chamber 16.
The above-described arrangement is known and will therefore not be described in further detail.
The side of the front wall 14 bordering the power chamber 16 is formed with a hollow and/or a recess 40, in which the front side of the front wall bordering the power chamber 16 is spaced somewhat farther from the piston 12 than the area of the front wall formed with the intake opening. An overall plate-shaped cylinder head recuperator 42 is storable in the recess 40, such that the cylinder head recuperator 42 at least substantially fills the recess 40, is at least substantially in abutment on the closed exhaust valve 26 and extends at least substantially flush with the area of the inner side of the front wall 14, in which the intake opening is disposed. The closed intake valve 22, the area of the front wall 14 surrounding the intake opening and the side of the cylinder head recuperator 42 facing towards the power chamber 16 thus advantageously form a planar boundary surface of the power chamber 16 when the cylinder head recuperator is located in its uppermost position (TDCR).
The cylinder head recuperator 42 is comprised of a material capable of withstanding high temperatures and has passages (
The cylinder head recuperator 42 is rigidly connected with a shaft 44, which is guided in a sealed manner through the front wall 14 and/or through the cylinder head and is actuated by a recuperator cam 46, which has two cam lobs lying substantially opposite of each other. The cams 24, 28 and 46 can be formed in a known manner on a common cam shaft that is driven by the not-illustrated crankshaft of the internal combustion engine.
The cylinder head recuperator 42 has a hole such that the injection nozzle 30 projects through the cylinder head recuperator into the power chamber 16.
The piston 12 includes a combustion bowl 54 that is overall w-shaped in cross-section.
The function of the described arrangement is as follows:
According to
The position of the cylinder head recuperator according to
After the intake stroke has ended and with the exhaust valve 22 closed, when the piston 12 moves from its BDC toward the TDC to compress the intaken charge, the cylinder head recuperator 42 is moved by a lob of the recuperator cam 46 from its TDCR into a bottom dead center (BDCR). The stroke of the cylinder head recuperator 42 is advantageously somewhat larger than the depth of the recess 40, so that the cylinder head recuperator 42 moves out of the recess 40 and fresh charge goes into the recess 40 by passing around the cylinder head recuperator 42. As is apparent, the stroke of the cylinder head recuperator 42 between TDCR and BDCR is considerably smaller than the stroke of the piston between its TDC and BDC.
When the piston 12 moves into its TDC, the cylinder head recuperator 42 is moved back into the recess 40. As a result, the piston 12 advantageously abuts at least substantially on the cylinder head recuperator 42, so that compressed fresh charge is pressed out of the recess 40 through the cylinder head recuperator 42 into the combustion bowl 54.
At the TDC of the piston, the position according to
When the exhaust valve 20 opens in the subsequent exhaust cycle during the movement of the piston 12 from its BDC into the TDC, the cylinder head recuperator 42 first moves out of its TDCR before the beginning of the opening movement of the exhaust valve and completely moves out of the recess 40 at least before the end of the exhaust cycle. The movement stroke of the cylinder head recuperator 42 is advantageously somewhat larger than the opening stroke of the exhaust valve. At the end of the exhaust stroke, when the piston reaches its TDC, the cylinder head recuperator moves back into its TDCR in accordance with the closed exhaust valve 26.
During the illustrated movement sequences, the following heat transfers take place:
After the piston 12 has moved through its BDC, at the beginning of the exhaust up to about 60° after BDC, the cylinder head recuperator 42 is not completely moved out of the recess 40, so that the axis-parallel outer edge of the cylinder head recuperator 42 forms, with the axis-parallel inner perimeter wall of the recess 40, a ring-shaped gap having a small opening cross section, so that the initially very hot combustion gases flow through the cylinder head recuperator 42 and through the open exhaust valve into the exhaust channel 20. With further movement of the piston 12 toward the TDC, the cylinder head recuperator 42 is completely moved out of the recess 40 by the recuperator cam 46, so that the now-cooler, combusted gas goes into the exhaust channel 20 by passing around the cylinder head recuperator 42. In this way, the cylinder head recuperator 42 is intensively heated by the exhaust gas during the exhaust stroke. Depending upon the operational conditions of the internal combustion engine, e.g., charged or not charged, the cylinder head recuperator 42 can be moved completely out of the recess already at the BDC of the piston or for example at 120° after BDC.
When the cylinder head recuperator 42, which was moved completely out of the recess 40, is moved back into the recess 40 near the end of the compression stroke (
The cylinder head recuperator 42 advantageously can be moved completely out of the recess 40, so that the inner perimeter wall of the recess 40 and the outer perimeter of the cylinder head recuperator 42 can be formed in a complementary axis-parallel manner, and gas flow must take place substantially through the cylinder head recuperator 42 as soon as it is at least partially located in the recess 40.
As is apparent from the preceding discussion, the movement of the cylinder head recuperator 42 relative to the recess 40 during the compression stroke can be different from the movement during the exhaust stroke, so that the two cam lobs of the cylinder head recuperator 42 can be different.
With reference to
The exemplarily-described arrangement can be modified in various ways. For example, the wall of the combustion bowl 54 can be thermally isolated relative to the piston 12.
If the internal combustion engine is constructed as an Otto-engine, a spark plug can additionally be provided. Further, the mixture formation can take place externally, so that the injection nozzle 30 can be replaced by a spark plug.
Number | Date | Country | Kind |
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102011111761.3 | Aug 2011 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/003511 | 8/17/2012 | WO | 00 | 2/20/2014 |