KR20090128459A - Improved two-stroke engine - Google Patents

Abstract

The invention relates to a two-stroke crosshead engine with at least one cylinder (2) and a piston (4) reciprocating therein and provided with a piston rod (5) for transmission of power, said cylinder (2) being provided with inlet means for supplying scavenge air in to the cylinder (2), with means (18) for providing for ignition and combustion during the combustion stroke, and with exhaust valve means (9). The inlet means include channel means (10) for leading scavenge air through the piston into the cylinder (2) and inlet valve means (11,12) arranged on the piston for controlling the supply of scavenge air into the cylinder (2) through the channel means (10).

Description

Improved two-stroke engine {IMPROVED TWO-STROKE ENGINE}

The invention has at least one cylinder, as shown in the preamble of claim 1, and one piston reciprocating therein and provided with one piston rod for power transmission, said cylinder It is provided with an inlet means for supplying scavenge air into a cylinder, and relates to a two-stroke crosshead engine having means provided for ignition and combustion in a combustion stroke.

In a crosshead engine, the reciprocating piston in the cylinder is not directly connected to the connecting rod but through a piston rod slidably supported by the engine. Thus, together with the piston, the piston rod can only reciprocate in the cylinder. In this two-stroke engine of this kind, the scavenging supply has normally been made through a scavenging port arranged under the cylinder lighter, whereby the piston itself opening and closing the three ports at a particular time in the combustion cycle. As a result, an oil film that lubricates the cylinder and the piston with the piston ring is destroyed each time the piston moves past the inlet of the port. This worsens the wear of the cylinder lighter and the piston with the piston ring.

In an overloaded crosshead engine, the piston has a high heat load. Cooling is usually done by cooling oil which is supplied and discharged through the holes in the piston rod, which leads to a rather complicated system.

In addition, in a two-stroke crosshead engine, the introduction point of the scavenging is limited to the shape and position of the scavenging port, and is therefore independent of the load of the engine in each case.

It is an object of the present invention to provide an improved two-stroke crosshead engine that can solve the above-mentioned problems of the prior art. The object of the present invention can be substantially achieved as disclosed in claim 1 and other claims.

The basic concept of the present invention is to substantially change the path for supplying the scavenging into the cylinder. According to the present invention, the inlet means includes channel means for supplying scavengers to the cylinder through the piston, and intake valve means disposed on the piston for controlling the scavenging supply in the cylinder through the channel means.

This new solution has many advantages. Since there is no longer an inlet port located in a fixed place in the cylinder liner that negatively affected the lubricant film, scraping with the piston ring and the cylinder liner and abrasion of the piston can be reduced, which means that the life of the parts Will be extended. The piston and the intake valve means can be cooled by scavenging. This is particularly advantageous because the more air needed for combustion, the greater the cooling flow through the piston is, so the total amount of available cooling air follows the output of the engine. As a result, conventional oil cooling may be reduced or even not used at all by certain components. This new solution also affects the timing of the intake valve means. This is because by changing the precise opening and closing time of the intake valve means, the scavenging time according to the load situation can be changed accordingly in order to give optimum performance.

The intake valve means comprises a valve face on the piston associated with the channel means, the intake valve, and the like, which valve preferably has the shape of a disk valve movably supported on the piston rod with respect to the valve face.

The timing of the intake valve means can be usefully configured by providing a control rod functionally connected with the intake valve means to the piston rod for its control. The control valve means is operated hydraulically or pneumatically.

In a practical embodiment, the piston rod is provided with a chamber, the chamber having an auxiliary piston element movably disposed therein and fixed to the disc valve. Such a chamber may be arranged to communicate through a hydraulic pressure source and a piston rod for controlling the operation of the auxiliary piston element and the operation of the intake valve means.

In order to ensure proper function, the control valve means are forced by the spring means towards the closed position of the intake valve means.

The channel means may comprise a plurality of separate channels arranged to be connected in series with the desired source.

The invention has the advantage that it can be applied independently of the actual driving mode of a two-stroke engine. Thus, it may be an engine operating on the principle of diesel, whereby the means provided for ignition and combustion comprise injection valve means for supplying fuel to the cylinder. In this case, in practice, the engine is provided with a turbocharger for compressing the scavenged air to be supplied to the cylinder. Alternatively, it may be a gasoline engine, in which case the means for ignition and combustion comprise spark plug means. In this case, as is known in the art, the fuel and the scavenging may be configured before the scavenging is supplied to the cylinder.

In the following, the present invention is described with reference to the accompanying drawings for illustrative purposes only.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a cross section of a cylinder of a two-stroke crosshead engine according to an embodiment of the present invention, showing a state in which both the intake and exhaust valves are opened in the intake and scavenging strokes.

FIG. 2 is a view of the cylinder of FIG. 1 showing the moment of ignition at the end of the compression stroke.

Fig. 3 is a view showing the cylinder of Fig. 1 after the power stroke, showing the state in which the exhaust valve is opened in the exhaust stroke.

4 is a view showing an embodiment of a piston according to the present invention.

FIG. 5 is a view illustrating a cross section taken along the line VA-VA of FIG. 4.

In the drawings, reference numeral 1 denotes a part of an engine block including a cylinder 2 which is mainly defined by the cylinder liner 3. The cylinder 2 is provided with a piston 4 configured to move its interior reciprocally. Since this engine is a crosshead engine, the piston 4 is fixed to the piston rod 5, and the piston rod 5 is slidably supported on the cylinder block 1 or other parts fixed thereto, so that the piston The rod 5 also reciprocates. The mutual fixing relationship between the piston 4 and the piston rod 5 can be configured by a known method, for example, by means of the screw 20 as shown in FIGS. 4 and 5. The transmission of power from the piston 4 and the piston rod 5 can be through a connecting rod (not shown) as is known in the art.

The engine block 1 is provided with a chamber 6 for supplying air into the cylinder 2. The chamber 6 is connected with an inlet pipe or duct (not shown). In order to supply the scavenging air into the cylinder, the upper part of the piston 4 and the piston rod 5 is opened in the head part of the piston 4 toward the cylinder 2 according to the design and mutual fixation state thereof. A plurality of channels 10 are provided that form a common inlet opening configured to form the face 11. Concerned with this valve surface 11 is an intake valve 12 having a stem 12a. The intake valve 12 is slidably mounted and guided in the piston rod 5 by means of its stem 12a.

The upper end of the cylinder 2 includes an exhaust valve 9 which is configured in the cylinder head 7 of the engine and controls the exhaust duct 8. The cylinder head 7 is also equipped with means 18 for providing ignition and combustion. Depending on the mode of operation of the engine, this means 18 may be injection means arranged to inject fuel for the desired ignition at the end of the compression stroke. In this case, the problem is with the diesel engine. Alternatively, the means 18 may be spark plug means for igniting a mixture of fuel and scavenged gas supplied through the chamber 6 into the cylinder 2.

In FIG. 1, the intake and scavenging stroke will be described, whereby the piston 4 is raised and the intake valve 12 is opened to allow the scavengers to enter the cylinder 2. At the same time, the exhaust gas is removed through the exhaust valve 9. The exhaust valve 9 and the intake valve 12 are then closed at a particular stage, followed by a compression stroke. In Fig. 2, the scavenging is compressed and the gas in the cylinder 2 is ignited at the end of the compression stroke, and the ignition method depends on the operation method of the engine. Subsequently there will be a power stroke. At the end of the power stroke the piston 4 is descending and the exhaust valve 9 is opened. The intake valve 12 is in a closed state, the pressure is released and the exhaust gas is pushed out of the cylinder to the exhaust duct 8 as shown in FIG. The cycle resumes immediately after the bottom dead center, and in the first stage of intake and scavenging stroke as described in FIG. 1, the exhaust valve 9 is still open, so that the exhaust valve 9 is Until it is closed again, the sucked air pushes the remaining exhaust gas into the exhaust duct 8.

4 and 5 show an embodiment in which the piston rod is fixed to the piston by means of bolts 20. As shown, the channels 10 are configured through both the piston rod 5 and the piston 4 and are connected to the valve face 11 in the piston 4 to form a constant chamber. As an alternative solution to that shown, the piston rod is integrally coupled to the piston to form one part. However, this makes it impossible to use different materials for the piston and the piston rod.

To control the timing of the intake valve 12 so as to better cope with the load situation of the engine in each case, the intake valve 12 includes a chamber 14 disposed in the piston rod 5. And a control valve 13 functionally connected thereto. In the chamber 14, an auxiliary piston element 15 fixed to the intake valve 12 in the stem 12a is provided to be movable. This chamber 14 is a hydraulic source 19 (shown schematically in FIG. 1) and the piston rod 5 for controlling the movement of the auxiliary piston element 15, that is, the operation of the entire intake valve 12. It communicates through the duct 16 inside. The control valve 13 is exerted a force toward the closed position of the intake valve 12 by a spring 17. Note that the force for opening the intake valve is assisted by the scavenging pressure in the opening phase of the valve, and the closure is assisted respectively by inertia. If desired, instead of one spring 17, multiple springs may be used to ensure proper closure of the valve 13.

Hydraulic control can be configured in a manner known in the field of hydrodynamics. For that purpose it is also possible to use pneumatic pressure instead of hydraulic pressure. In various cases, in order to control the supply of the scavenging into the cylinder in accordance with the load situation of the engine, control logic is required for the operation timing and proper operation of the control valve 13.

It is apparent that the present invention is not limited only to the above-described embodiments, but can be configured in many different embodiments within the scope of the inventive concept as defined in the appended claims. Therefore, the application of the present invention is independent of the exact number of cylinders in the engine, and each cylinder may be provided with one or more exhaust valves, and the exact method of securing the piston to the piston rod may be chosen as desired in each case. Can be. In addition, the operation of the control valve may be configured in various ways depending on the mechanical operation.

Claims (9)

At least one cylinder (2) and a piston (4) provided with a piston rod (5) for reciprocating and transmitting power in the cylinder, wherein the cylinder (2) is provided with a cylinder (2). In a two-stroke crosshead engine provided with intake means for supplying into, a means for ignition and combustion during combustion stroke, and an exhaust valve means (9), the intake means is provided with Channel means (10) for introduction into the cylinder (2) and intake valve means (11, 12) disposed on the piston for controlling the amount of scavenging supplied through the channel means (10) into the cylinder (2). Two-stroke crosshead engine comprising a. 2. The intake valve means (11, 12) according to claim 1, in cooperation with the channel means (10) and the intake valve (12), etc., preferably cooperate with the valve face (11) and on the piston rod (5). And a valve face (11) on the piston in the shape of a disk valve that is movably supported. The two-stroke crosshead according to claim 1 or 2, characterized in that the piston rod (5) is provided with a control valve means (13) functionally connected to the intake valve means (11, 12) for its control. engine. 4. Two-stroke crosshead engine according to claim 3, characterized in that the control valve means (13) are operated hydraulically or pneumatically. 5. The piston rod (5) according to claim 4, wherein the piston rod (5) is provided with a chamber (14) having an auxiliary piston element (15) movably provided therein and fixed to an intake valve (12). Two-stroke crosshead engine, characterized in that it is configured to communicate with the hydraulic source 19 and the piston rod 5 in order to control the operation of the auxiliary piston element 15 and the operation of the intake valve means 11, 12. . A two-stroke according to any one of claims 3 to 5, characterized in that the control valve means (13) are forced by the spring means (17) towards the closed position of the intake valve means (11, 12). Crosshead engine. 2. A two-stroke crosshead engine according to any of the preceding claims, characterized in that the channel means (10) comprise a plurality of individual channels (10) arranged to be connected in series with the scavenging source (6). 2. The two-stroke crosshead engine according to claim 1, wherein the means for ignition and combustion comprise injection valve means for supplying fuel into the cylinder. The two-stroke crosshead according to any one of claims 1 to 7, wherein the means for ignition and combustion (18) comprise spark plug means, which are purged with air before the fuel is supplied into the cylinder. engine.

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