DE102013006703B4 - Internal combustion engine with re-expansion of the working gas in the partial load range - Google Patents

Abstract

In internal combustion engines, a high compression ratio and the operation of the cylinder with high load is low in efficiency. It would also be advantageous, one could choose the expansion ratio larger than the compression ratio. There are four-cylinder engines in which the two outer cylinders are operated at higher load in the lower part-load range and the valve actuation is switched off for the two inner cylinders. The compression ratio and expansion ratio are the same here. Another variant exists as a three-cylinder engine, in which only the two outer cylinders are fired and the middle cylinder is used with a larger displacement than one of the two outer cylinders to further expand the working gas of cylinders 1 and 3, this variant requires more displacement to represent a specific power. Now proposed is an engine variant in which of four cylinders in the lower part load range, the load in the two outer cylinders is raised and the two inner cylinders are used for Nachexpandieren the exhaust gas of the two outer cylinders. This is done by stopping the operation of certain valves. in the upper load range, all cylinders are fired.

Description

In view of constantly increasing fuel prices, limited crude oil reserves and environmental protection, which is gaining more and more importance, it seems necessary to strive for further improvement measures in the energy converter internal combustion engine, which is used in large numbers.

Basically, a high compression ratio in a four-stroke internal combustion engine is accompanied by a high degree of thermodynamic efficiency. However, this one is limited in a desired design of a high compression ratio in that one must observe restrictions resulting from the risk of knocking during combustion, so that you can no longer ignite the cylinder charge in the normally effective optimal phase position, on the other hand It should be noted that in the vicinity of the top dead center of the charge exchange sufficient distance between the partially open valves and the piston must be ensured in order to avoid a collision of the components. It is therefore not always possible from thermodynamic and structural conditions to realize a correspondingly small combustion chamber volume, so that a high-efficiency, high compression ratio results in a four-stroke internal combustion engine. In order to take these constraints into account as advantageously as possible, or to avoid this conflict in the most advantageous manner possible, there are various approaches.

For example, an engine concept is currently being developed in DE 601 16 942 T2 discussed, in which a way is shown how to meet the advantageous from efficiency aspects requirement for a motor variant with a larger expansion ratio than compression ratio. This problem is also in the dissertation D386 2006, page 71 ff, by Dr.-Ing. Gert Schreiber, University of Kaiserslautern, discussed.

When in the DE 601 169 42 T2 proposed engine variant is a three-cylinder in-line engine in which the two outer cylinders are operated in conventional four-stroke mode, the middle, inner cylinder, however, differs from the outer in that it has about twice as large a stroke volume as one of the two outer cylinders and that it is operated in two-stroke mode, wherein this is mutually, in each revolution, is acted upon by one of the two outer cylinder with the exhaust gas. Thus, in the exhaust stroke of one of the two outer cylinders, which is spatially connected in each case by an overflow with the middle, inner cylinder, the burned working gas inasmuch as perform further expansion work, as in the sum of the two cylinder volumes of outer cylinder extending from bottom dead center moves to top dead center and from inner cylinder, which thereby moves from top to bottom dead center, results in an overall increase in the volume of the working gas. By this expanded expansion of the working gas can be obtained in the combustion of a certain amount of fuel more mechanical work and thus the efficiency of the engine can be increased.

At this in DE 601 169 42 T2 proposed type of engine, which is also referred to as 5-stroke engine, a further, additional cylinder is required in which the post-expansion of the working gas of the adjacent outer cylinder takes place, which is not operated fired.

However, with the additional thermodynamic energy gained from this concept, the mechanical losses incurred by this additional cylinder must be covered, thereby reducing the resulting efficiency benefit. In this five-stroke engine type, more displacement is required to cover a certain performance spectrum, which increases the space required, the weight and the manufacturing costs. As relevant prior art also have internal combustion engines according to the publications US 4 250 850 A . EP 2 267 291 A2 . US 5,699,758 A and DE 31 29 609 A1 to apply.

The invention has for its object to provide an internal combustion engine variant, can be switched in the partial load cylinder from the fired operation on Nachexpansionsbetrieb the working gas of fired operated cylinders, so that you can achieve thermodynamic efficiency advantages, without required Mehrhubraum.

This object is achieved by the features described in the claims.

An internal combustion engine concept is proposed in which, of four cylinders arranged in a row, which are operated in the upper part-load range and at full load in the four-stroke mode, the two inner cylinders 2 and 3 can be switched in the lower part load range to unfired Nachexpansionsbetrieb the working gas of the two outer cylinders. 1 and 4. The operated in Nachexpansionsmodus cylinders 2 and 3 operate in two-stroke mode.

In an engine of the type proposed, the phasing of the crankshafts in an array of 4 cylinders in series is selected so that the two outer pistons of cylinders 1 and 4 become located approximately in top dead center and the two inner pistons of cylinders 2 and 3 are located approximately in the bottom dead center. In a firing order in this row of cylinders of 1-3-4-2 or 1-2-4-3, in a four-stroke process, flows in the lower part load range after the expansion stroke in cylinder 1, the Ausschiebetakt this cylinder, the working gas this cylinder by a transfer channel ( 1 ) in cylinder 2. This overflow can be opened and closed by controlling valves that limit the working volume in a cylinder when closed. Cylinder 2 is in turn via an overflow channel ( 1 ) connected to cylinder 3. Also, this overflow can be opened and closed by controlling valves that limit the working volume in a cylinder in the closed state. Due to the reduction of the volume in cylinder 1 and the increase in volume in cylinders 2 and 3 at Ausschiebetakt in cylinder 1 results in total for the working gas volume increase.

In the next power stroke, in which the working gas from cylinder 1 is in cylinders 2 and 3, the working gas is pushed out of the cylinders 2 and 3 by the cylinder volume reduction caused by the piston movement through one of the cylinder 2 or cylinder 3 leading away channels Cylinders 2 and 3 in turn via an overflow channel ( 1 ) are spatially interconnected.

After the working or expansion stroke in cylinder 4, during the exhaust stroke of this cylinder, the working gas of this cylinder flows through an overflow channel in cylinder 3. This overflow can be opened and closed by controlling valves that limit the working volume of a cylinder in the closed state. Cylinder 3 is connected via an overflow channel with cylinder 2. Due to the reduction in volume in cylinder 4 and the increase in the volume in cylinder 3 and 2 results in the exhaust stroke in cylinder 4 for the working gas total volume increase. At the next power stroke, in which the working gas from cylinder 4 is in cylinders 3 and 2, the working gas is pushed out of the cylinders 3 and 2 by the piston movement through one of the cylinder 3 or cylinder 2 leading away channels, wherein cylinder 3 and 2 in turn are spatially interconnected via an overflow channel. In the lower part-load range, in Nachexpansionsbetrieb the cylinders 2 and 3, the nachexpandierte working gas is alternately discharged once via the outlet channel of cylinder 2, once via the outlet channel of cylinder 3, wherein cylinders 2 and 3 in turn are spatially connected via an overflow channel. This overflow can be opened and closed by controlling valves that each limit a working volume in the cylinder in the closed state.

The mutual discharge of the working gas from cylinder 2 and cylinder 3, once on the exhaust port of cylinder 2, once on the exhaust port of cylinder 3, the fact that in fired operation of the two inner cylinders 2 and 3, respectively, the exhaust valves for this benefit Exhaust ports are also opened during the corresponding piston stroke. In the upper part-load range and in the full-load range, relating to the entire engine, the overflow channels remain closed from cylinder 1 to cylinder 2, cylinder 4 to cylinder 3 and cylinder 2 to cylinder 3 by switching off the valve actuation for all cycles of the complete work cycle and in the lower part load range, concerning the whole engine, the valve actuation for the intake ports of cylinder 2 and cylinder 3 and for the exhaust passage (s) of cylinder 1 and cylinder 4 which do not lead to re-expansion of the working gas in cylinders 2 or 3 may be for all Cycles of the complete work cycle are shut down.

The control of the charge exchange is carried out only with valves that limit the cylinder working volume in the closed state, in the case of fired operation in the upper part-load range and / or. In the full load combustion takes place, or prevent an influx into the cylinder, or an outflow from the cylinder.

In the lower part load range, in Nachexpansionsbetrieb the cylinder 2 and 3, the control of the valves for the connecting channel of cylinder 2 and cylinder 3 is such that there are, based on a crankshaft revolution, phases in which these valves are fully closed. For the valve lift course for the valves of this connecting channel of the cylinders 2 and 3 is designed so that, based on a crankshaft revolution, in the range of high piston speeds large valve lift, in the range of low piston speeds, ie in the vicinity of the dead center, the valves have low valve lift, or are closed. In the upper part-load range and full-load range, regarding the overall engine, the two inner cylinders 2 and 3 are fired at a total arrangement of 4 cylinders and in a 4-stroke cycle with a total cycle angle length of 720 ° crank angle relative to each other by 360 ° crank angle in total cycle life operated.

It is possible to realize the desired engine performance in an internal combustion engine in the lower part-load range so that when 4 cylinders arranged in series for the two outer cylinders 1 and 4, the load is raised, whereas the two inner cylinders are no longer filled with fresh gas and no longer be fired. The valve actuation for the two inner cylinders is completely shut down for this part load operation. Such engine concepts are now being used in mass production, for example at Volkswagen AG.

When operating in the lower part load range also in an arrangement of 4 cylinders in series, the desired performance is represented by the fact that the load of the two outer cylinders 1 and 4 is raised and the two inner cylinders 2 and 3 are no longer supplied with fresh gas become.

The valve actuation for the fresh gas supply channels of the two inner cylinders 2 and 3 is completely shut down in this part load operating mode. When Ausschiebetakt of cylinder 1, the exhaust gas flows from this cylinder through an overflow channel leading to the adjacent cylinder 2, in cylinder 2, this is spatially connected by an overflow channel with cylinder 3. For the working gas thus results in the sum of the reduction in volume in cylinder 1 and the increase in volume in cylinders 2 and 3 total volume increase. The working gas from cylinder 1 can thus perform further expansion work in cylinders 2 and 3, which means an increase in efficiency, or a reduction in fuel consumption. At the next power stroke, in which now the working gas from cylinder 1 is in cylinders 2 and 3 and the pistons of cylinders 2 and 3 move from the bottom dead center to the top dead center, the working gas flows at a (full load) firing order of 1- 3-4-2 in this row of cylinders, as would be the case in fired operation of all cylinders of this series, through the exhaust port of cylinder 3 into the exhaust tract, cylinders 2 and 3 are spatially interconnected by an overflow.

In this work cycle, the exhaust gas from cylinder 3 would also flow when operating with all four cylinders fired this cylinder series. If the working gas from cylinder 4 is reexpanded in cylinders 2 and 3, this flows during the upward movement of the pistons of cylinders 2 and 3 through the exhaust port of cylinder 2 into the exhaust gas tract.

In a firing order of 1-2-4-3 present in this cylinder bank, the working gas of cylinder 1, which is reexpanded in the cylinders 2 and 3, flows through the exhaust passage as the pistons of cylinders 2 and 3 move from lower to top dead center from cylinder 2 into the exhaust tract. Even when operating with all four fired cylinders of this cylinder row, the exhaust gas would flow out of cylinder 2 at this power stroke. If the working gas from cylinder 4 in cylinders 2 and 3 is reexpanded in an existing firing order of 1-2-4-3, this flows during the upward movement of the piston from cylinder 2 and 3 through the exhaust port of cylinder 3 into the exhaust tract.

The internal combustion engine concept proposed here makes it possible to make better use of the combustion heat by reexpansion of the working gas from fired cylinders in unfired cylinders, without special new variants of basic engines (eg three-cylinder engine, with the middle cylinder having approximately twice the displacement of one of the two outer cylinder), without resulting disadvantages in the specific power (KW / dm ³ ), (in the upper part load and at full load, this engine variant can be operated with all cylinders fired), without much additional space required and without much required additional weight. With regard to the torque curve of the proposed engine concept results in the lower part load area, when using the two inner cylinder for Nachexpansion of the working gas from the two outer cylinders advantages over engines in which in the partial load range of four cylinders arranged in series z. B. the two inner cylinders are switched off by complete shutdown of the valve actuation of these cylinders.

When the engine is operating in the upper part-load range and at full load, the engine concept according to the invention exhibits no disadvantages compared to previously conventional engines since all four cylinders are fired. Also constructive no new territory must be entered, the proposed engine variant can be generated from known components.

Claims (2)

Combustion engine with Nachexpansion of the working gas in the partial load range, with four cylinders in a row, in which the phase angle of the crankcranes is selected so that when the two outer pistons of cylinders 1 and 4 are in top dead center +/- 30 ° crank angle, the two inner cylinder of piston 2 and 3 are in the bottom dead center position +/- 30 ° crank angle, the cylinders are operated in the upper part load range and full load in four-stroke mode, and in the lower part load area, the two inner cylinders 2 and 3 are switched to unfired Nachexpansionsbetrieb the Working gas from the two outer cylinders 1 and 4, and in the lower part load area, the desired performance, concerning the entire engine, by increasing the load of the two outer cylinders 1 and 4 when using the two inner cylinders 2 and 3 Nachexpansion of the working gas from the two outer cylinders 1 and 4 is shown, and in the lower part load range after the working or expansion stroke in cylinder 1, the Ausschiebetakt this cylinder, the working gas of this cylinder by a overflow, by controlling valves in the closed state, the working volume in a cylinder limit, can be opened and closed, in cylinder 2 flows over, with cylinders 2 and 3 in turn by a transfer port, which are opened and closed by controlling valves which limit the working volume of a cylinder in the closed state can, is spatially interconnected, resulting in an overall increase in volume due to the volume reduction in cylinder 1 and the increase in volume in cylinders 2 and 3 at Ausschiebetakt in cylinder 1 for the working gas, and at the next power stroke, in which the working gas from cylinder 1 in Cylinder 2 and 3, the working gas is pushed out of the cylinders 2 and 3 by the cylinder volume reduction caused by the piston movement through one of the cylinders 2 or 3 leading away from the cylinders 2 and 3, characterized in that the control of the charge exchange is carried out only with valves which in the closed state Limit cylinder working volume, and in the lower part load range, with Nachexpansionsbetrieb the cylinders 2 and 3, the nachexpandierte working gas is alternately discharged once via the outlet channel of cylinder 2, once via the outlet channel of cylinder 3. Internal combustion engine with post-expansion of the working gas in the partial load range according to claim 1, characterized in that in the lower part-load range, in Nachexpansionsbetrieb the cylinder 2 and 3, the control of the valves for the connecting channel of cylinder 2 and cylinder 3 is such that it, based on a crankshaft revolution , There are phases in which these valves are completely closed.

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