KR101855767B1 - Cylinder deactivation engine - Google Patents

Abstract

A cylinder-idling engine according to an embodiment of the present invention includes at least one idle cylinder in which idling is selectively performed; At least one non-dormant cylinder in which no dwell is performed; A three-stage variable valve lift device provided on an intake side of the dormant cylinder and operated to realize a lift of the valve as one of three lifts; A two-stage variable valve lift device provided on an exhaust side of the dormant cylinder and an intake side of the non-dormant cylinder, the two-stage variable valve lift device being operated to implement the lift of the valve in one of two lifts; An oil pump for generating a hydraulic pressure for operating the three-stage variable valve lift apparatus and the two-stage variable valve lift apparatus; A plurality of oil control valves operable to selectively supply oil pressure generated from the oil pump to the three-stage variable valve lift device and the two-stage variable valve lift device, respectively; An intake oil gallery passing through both the pivot shaft of the three-stage variable valve lift device and the pivot axis of the two-stage variable valve lift device provided on the intake side of the non-idle cylinder; An exhaust oil gallery passing through all of the pivot shafts of the two-stage variable valve lift device provided at the exhaust side of the dormant cylinder; And a plurality of oil supply passages for communicating the intake oil gallery and the exhaust oil gallery with the plurality of oil control valves.

Description

[0001] CYLINDER DEACTIVATION ENGINE [0002]

The present invention relates to a cylinder dumped engine, and more particularly, to a variable valve lift apparatus for realizing variable valve lifting and cylinder stopping, and a hydraulic cylinder for operating a variable valve lift apparatus, .

Generally, an internal combustion engine is an engine in which a mixer is combusted in a combustion chamber and is operated by energy generated by the combustion heat. Such an internal combustion engine is mainly a multi-cylinder engine having a plurality of cylinders for increasing the output of the engine and reducing noise and vibration.

Recently, there has been developed an engine cylinder stopping device that improves fuel economy by deactivating some cylinders of a plurality of cylinders provided in the engine when the engine is in a low horsepower state due to an increase in energy cost.

In the cylinder stopping method used in such a conventional cylinder stopping device, a mixer is not injected into a cylinder of a plurality of cylinders and ignition is not performed, and a mixer is injected into only the remaining cylinders so that the engine is operated.

For example, in the case of a four-cylinder engine, two cylinders are not injected with a mixture and ignited, and the remaining two cylinders only operate the engine.

On the other hand, a variable valve lift technique which selectively implements a zero lift of the valve so that a mixer is not injected into the cylinder to be hung can be applied.

However, in the cylinder dormant engine implemented by the existing cylinder dormancy device, the valve of the cylinder in which the dormancy is not performed operates with a constant normal lift, and the valve lift can not be implemented as an appropriate lift according to the rotation speed of the engine. Further, if the configuration for varying the valve lift of the cylinders in which suspension is not performed becomes complicated, the weight and cost of the engine can be excessively increased. Furthermore, if the configuration of the hydraulic pressure supply for varying the rest of the cylinder and the valve lift is complicated, the productivity may be deteriorated.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a cylinder braking engine which realizes a stoppage of some cylinders or a variable valve lift of all cylinders, .

According to an aspect of the present invention, there is provided a cylinder dumped engine including at least two cylinders, and a cylinder dumped engine for selectively performing a stop of some of the cylinders.

The cylinder diesel engine comprising: at least one dormant cylinder in which a dormant is selectively performed; At least one non-dormant cylinder in which no dwell is performed; A three-stage variable valve lift device provided on an intake side of the dormant cylinder and operated to realize a lift of the valve as one of three lifts; A two-stage variable valve lift device provided on an exhaust side of the dormant cylinder and an intake side of the non-dormant cylinder, the two-stage variable valve lift device being operated to implement the lift of the valve in one of two lifts; An oil pump for generating a hydraulic pressure for operating the three-stage variable valve lift apparatus and the two-stage variable valve lift apparatus; A plurality of oil control valves operable to selectively supply oil pressure generated from the oil pump to the three-stage variable valve lift device and the two-stage variable valve lift device, respectively; An intake oil gallery passing through both the pivot shaft of the three-stage variable valve lift device and the pivot axis of the two-stage variable valve lift device provided on the intake side of the non-idle cylinder; An exhaust oil gallery passing through all of the pivot shafts of the two-stage variable valve lift device provided at the exhaust side of the dormant cylinder; And a plurality of oil supply passages for communicating the intake oil gallery and the exhaust oil gallery with the plurality of oil control valves.

The three valve lifts implemented by the three-stage variable valve lift apparatus are a zero lift, a normal lift, and a high lift, and the three-stage variable valve lift apparatus can be operated by hydraulic pressure to implement a normal lift or a high lift.

The two valve lifts implemented by the two-stage variable valve lift apparatus disposed on the exhaust side of the idle cylinder are a zero lift and a normal lift, and the two-stage variable valve lift apparatus is operated by hydraulic pressure to implement a zero lift .

The two valve lifts implemented by the two-stage variable valve lift apparatus disposed on the intake side of the non-idle cylinder are a normal lift and a high lift, and the two-stage variable valve lift apparatus can be operated by hydraulic pressure to implement a high lift have.

The intake air gallery and the exhaust oil gallery may each be formed along one straight line.

The oil control valve includes first, second, third and fourth oil control valves, and four drive modes can be implemented according to opening and closing of the first, second, third and fourth oil control valves.

Wherein the plurality of oil supply passages include a first oil supply passage for communicating the intake oil gallery and the first oil control valve to supply hydraulic pressure to one pivot shaft of the three-stage variable valve lift device; A second oil supply passage communicating the intake oil gallery and the second oil control valve to supply hydraulic pressure to a pivot shaft of a two-stage variable valve lift device disposed on an intake side of the non-idle cylinder; And a third oil control valve for supplying hydraulic pressure to the pivot shaft of the two-stage variable valve lift apparatus disposed on the exhaust side of the idle cylinder and the other pivot shaft of the three-stage variable valve lift apparatus, And a third oil supply passage communicating with the first oil supply passage.

Wherein the first oil supply passage communicated with the first oil control valve is branched into two bifurcated branches to connect each one of the pivot shafts of the three-stage variable valve- So that the hydraulic oil can be supplied to the intake oil gallery.

Wherein the plurality of oil supply passages are connected to a pivot shaft of a two-stage variable valve-lifting device disposed on an exhaust side of another idle cylinder and a pivot shaft of another one of the three-stage variable valve- And a fourth oil supply passage communicating with the exhaust oil gallery and the fourth oil control valve to supply the exhaust oil gallery and the fourth oil control valve.

And the plurality of oil supply passages may communicate with the intake oil gallery and the exhaust oil gallery through the hollow of the camshaft.

The four drive modes include a first mode in which all the valves of the dormant cylinder and the non-dormant cylinder are operated as a normal lift; A second mode in which the intake valve and the exhaust valve of the idle cylinder are operated as a zero lift, and the intake valve of the non-idle cylinder is operated as a normal lift; A third mode in which the intake valve and the exhaust valve of the idle cylinder are operated as a zero lift and the intake valves of the non-idle cylinder are operated as a high lift; And a fourth mode in which all the valves of the dormant cylinder and the non-dormant cylinder are operated as a high lift.

Wherein the first mode is implemented by closing all of the first, second, third and fourth oil control valves, the second mode is closed by the first and second oil control valves, And the third mode is implemented by opening the first, second and third oil control valves, and the fourth mode is implemented by opening the first and second oil control valves And the third and fourth oil control valves are closed.

In the intake air gallery, each portion through which the plurality of oil supply passages communicate with each other may be partitioned by a diaphragm.

In the exhaust oil gallery, each portion through which the plurality of oil supply passages communicate with each other may be partitioned by a diaphragm.

The at least two cylinders include first, second, third and fourth cylinders, wherein the first and fourth cylinders are non-resting cylinders, and the second and third cylinders are resting cylinders.

Wherein the intake oil gallery has a region communicating with the second oil supply passage from the side of the first cylinder, a region communicating with the first oil supply passage from the side of the second cylinder, A region communicating with the first oil supply passage at the second cylinder side, a region communicating with the supply passage, a region communicating with the first oil supply passage at the third cylinder side, a region communicating with the fourth oil supply passage at the third cylinder side, 2 region communicating with the oil supply passage may be partitioned by the diaphragm.

The exhaust oil gallery may be partitioned by a diaphragm in a region communicating with the third oil supply passage at the second cylinder side and a region communicating with the fourth oil supply passage at the third cylinder side.

As described above, according to the embodiment of the present invention, it is possible to realize variable valve lift of all the cylinders while implementing the rest of the rest cylinder.

Further, by implementing four modes of engine driving by the four oil control valves, it is possible to efficiently drive the engine according to the state of the engine and the running state of the vehicle.

Further, the construction of the oil gallery for realizing the cylinder rest and the variable valve lift can be simplified.

Thus, ultimately, the improvement of fuel economy can be maximized and the productivity can be increased.

1 is a perspective view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.
2 is a plan view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.
3 is a rear view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.
4 is a cross-sectional view taken along the line AA in Fig.
5 is a cross-sectional view taken along line BB in Fig.
6 is a plan view of a two-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.
7 is a side cross-sectional view of a two-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.
8 is a configuration diagram of a cylinder idle engine according to an embodiment of the present invention.
9 is a block diagram illustrating the supply of hydraulic pressure to implement four drive modes of a cylinder idle engine according to an embodiment of the present invention.
10 is a schematic view of an oil gallery according to an embodiment of the present invention.
11 is a table showing four drive modes of the cylinder idle engine according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention, FIG. 2 is a plan view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention, And FIG. 3 is a rear view of a three-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.

1 to 3, a three-stage variable valve lift apparatus 100 according to an embodiment of the present invention includes an outer body 110, a first inner body 120, a roller 160, A body 130, a connecting shaft 140, a first lost motion spring 150, and a second lost motion spring 151.

The outer body 110 selectively receives the rotational force of the cam shafts 10 and 20 and performs a lever motion and operates to open and close the valves 40 and 50. The cam shafts 10 and 20 are formed with a plurality of cams 30 so as to convert rotational movement of the camshafts 10 and 20 into lever movement of the outer body 110. Here, the valves 40 and 50 are the intake valve 40 or the exhaust valve 50 of the engine. Further, two spaces 112 and 113, through which the outer body 110 is vertically penetrated, are formed on the inner side of the outer body 110. That is, the outer body 110 has a predetermined length for lever movement and has a certain width and thickness to form two inner spaces 112 and 113 of the outer body 110. One of the two inner spaces 112 and 113 of the outer body 110 is referred to as a first inner space 112 and the other is referred to as a second inner space 113. [

The valve (40, 50) is connected to one end of the outer body (110), and a lever motion rotary shaft is provided at the other end. Herein, the axis of rotation of the lever movement of the outer body 110 is a pivot axis relative to a hydraulic lash adjuster (HLA) 190 (hereinafter referred to as a person skilled in the art) (See FIG. 10). The first inner space 112 and the second inner space 113 of the outer body 110 are opened to one end side of the outer body 110 so that the overall shape of the outer body 110 is' Shape. Further, the outer body 110 is formed with a partition 119 for partitioning the first inner space 112 and the second inner space 113 such that an "E" shape is formed.

In the following description, one end and the other end of the components provided or connected to the outer body 110 refer to a part of the outer body 110 in the same direction as the one end and the other end, respectively.

The first inner body 120 is disposed in the first inner space 112 of the outer body 110. One end of the first inner body 120 is rotatably connected to one end of the outer body 110. Further, the first inner body 120 receives the rotational force of the cam shafts 10 and 20 and performs a lever movement, and is operated to selectively open and close the valves 40 and 50. Furthermore, a space (124) penetrating in the vertical direction is formed inside the first inner body (120). That is, the first inner body 120 has a predetermined length and has a predetermined width and thickness to form an inner space 124 of the inner body 120.

The roller 160 is disposed in the inner space 124 of the first inner body 120. The roller 160 is rotatably connected to the first inner body 120. Further, the roller 160 is in rolling contact with any one of the plurality of cams 30 so as to convert rotational movement of the camshaft into lever movement of the outer body 110 or the inner body 120.

The second inner body 130 is disposed in the second inner space 113 of the outer body 110. One end of the second inner body 130 is rotatably connected to one end of the outer body 110. Further, the second inner body 130 receives the rotational force of the cam shafts 10 and 20 and performs a lever movement, and is operated to selectively open and close the valves 40 and 50. Furthermore, the second inner body 130 is in rolling contact with the other one of the plurality of cams 30. That is, the second inner body 130 has a predetermined length for lever movement, and has a predetermined width and thickness for rolling contact with the other cam 30.

The connection shaft 140 is rotatably connected to one end of the first inner body 120 and one end of the second inner body 130 and one end of the outer body 110. That is, the first inner body 120 and the second inner body 130 may rotate relative to the outer body 110 about the connecting shaft 140. [ One end of the outer body 110 connected to the first and second inner bodies 120 and 130 by the connecting shaft 140 is referred to as an outer connecting part 114 and the connecting shaft 140 One end of the first inner body 120 connected to the outer body 110 is called a first inner connecting part 122 and the other end of the second inner connecting part 122 connected to the outer body 110 by the connecting shaft 140 One end of the inner body 130 is referred to as a second inner connection portion 132. [ That is, the connection shaft 140 passes through the outer connection part 114, the first inner connection part 122, and the second inner connection part 132.

A valve contact portion 116 protruding from the outer connection portion 114 is formed at one end of the outer body 110. Two outer connecting portions 114 may be formed on both sides of one end of the opened outer body 110. Therefore, the valve abutment portion 116 may protrude outward from the two outer connection portions 114 to form two valve abutment portions. The two valve abutting portions 116 are brought into contact with the valves 40 and 50 so as to push the two intake valves 40 or the two exhaust valves 50 in accordance with the lever movement of the outer body 110 Function.

Meanwhile, a seating part 111 is formed at the other end of the outer body 110 to receive the HLA 190.

The seating part 111 may be formed to protrude from the other end of the outer body 110 to both sides. In the two seating portions 111, seating grooves 115 and 117 are formed so that one HLA 190 is seated. That is, the three-stage variable valve lift apparatus according to the embodiment of the present invention is a four-point supported variable valve lift apparatus supported by two valves and two HLA.

The seating groove 115 formed adjacent to the first inner body 120 is referred to as a first seating groove 115 and the seating groove 117 formed adjacent to the second inner body 130 Will be referred to as a second seating groove 117.

When the first inner body 120 is fixed to the outer body 110, the rotation of one of the cams 30 in rolling contact with the roller 160 causes the first inner body 120, The outer body 110 moves together with the outer body 110 about the lever movement axis. When the first inner body 120 fixed to the outer body 110 is released from rotation, the rotation of the cam 30 in a rolling contact with the roller 160 causes the first inner body 120 Only the connecting shaft 140 is moved around the lever.

When the second inner body 130 is fixed to the outer body 110, the second inner body 130 is rotated by the rotation of the other cam 30 in a rolling contact with the second inner body 130 And the outer body 110 move together with the outer body 110 about the rotational axis of the lever motion. Also, when the second inner body 130 fixed to the outer body 110 is released, only the second inner body 130 rotates the coupling shaft 140 by rotation of the other cam Lever to center.

The profile of one cam 30 in rolling contact with the roller 160 and the profile of the other cam 30 in rolling contact with the second inner body 130 are formed differently. Therefore, when the first inner body 120 and the outer body 110 are lever-moved together by the cam 30 which is in rolling contact with the roller 160 and when the second inner body 130 and the rolling contact When the second inner body 130 and the outer body 110 move together by the cam, the valve lift is realized. Here, the different valve lifts may be a normal lift and a high lift.

The first inner body 120 and the second inner body 130 are coupled to each other by a cam that is in rolling contact with the second inner body 130 while the first inner body 120 levers around the connecting shaft 140 by a cam that comes into rolling contact with the roller 160. [ A zero lift of the valve is realized when the second inner body 130 performs a lever movement about the connection shaft 140. [ Thus, cylinder pause is performed.

When the first inner body 120 is fixed to the outer body 110, the first lost motion spring 150 moves the outer rotor 110 relative to the outer body 110, 1 function to return the inner body 120 to its original position. In addition, the first lost motion spring 150 is arranged to be wound on the connection shaft 140.

The first lost motion spring 150 is formed with an outer fixing part 152 fixed to the outer body 110 and an inner fixing part 154 fixed to the first inner body 120. The outer fixing part 152 extends along the width direction of the outer body 110 so as not to interfere with the first inner body 120 and is fixed to the outer connecting part 114 of the outer body 110 . When the outer body 110 and the connection shaft 140 are formed integrally with each other, the outer fixing part 152 is fixed to the connection shaft 140 so that the outer body 110 can be fixed to the outer body 110 have.

The second lost motion spring 151 is rotated by the lever motion to rotate the outer body 110 relative to the outer body 110 in a state where the second inner body 130 is released from being fixed to the outer body 110. [ 2 function to return the inner body 130 to its original position. In addition, the second lost motion spring 151 is arranged to be wound on the connection shaft 140.

The second lost motion spring 151 is formed with an outer fixing part 153 fixed to the outer body 110 and an inner fixing part 155 fixed to the second inner body 130. The outer fixing part 153 extends along the width direction of the outer body 110 so as not to interfere with the second inner body 130 and is fixed to the outer connecting part 114 of the outer body 110 . When the outer body 110 and the connection shaft 140 are formed integrally with each other, the outer fixing part 153 is fixed to the connection shaft 140 so that the outer body 110 can be fixed to the outer body 110 have.

The first and second lost motion springs 150 and 151 are arranged to be wound on the connection shaft 140 so as to be easily fixed to the first and second inner bodies 120 and 130, A separate component for connecting the lost motion springs 150 and 151 to the outer body 110 or the first and second inner bodies 20 and 30 is not required.

For example, the first lost motion spring 150 is arranged to be wound on the rotation axis of the lever motion of the outer body 110, and a part of the first lost motion spring 150 is wound on the roller 160 The length of the rotation shaft of the roller 160 is increased and the first lost motion spring 150 is connected to the first inner body 120 through the rotation shaft 165, A separate component may be required to wind on the rotational axis of the lever motion.

The connection shaft 140 is arranged to pass through the outer connection part 114 of the outer body 110. The valve abutment portion 116 protrudes from the outer connecting portion 114 to both sides of the outer body 110 so that the length of the connecting shaft 140 and the length of the valve abutment portion 116, The overall width of the outer body 110 can be reduced.

4 is a cross-sectional view taken along the line A-A in Fig. 4 is a view illustrating a configuration for selectively fixing the first inner body 120 to the outer body 110. As shown in FIG.

4, the first inner body 120 further includes a stopper 126 and a latching pinhole 129. The outer body 110 is provided with a first ratchet pin 170, A hole 172, a hydraulic pressure supply hole 177, and a first latching spring 175 are further formed or provided.

The stopper 126 protrudes from the other end of the first inner body 120. When the first inner body 120 reaches the original position by the first lost motion spring 150, And the other end of the inner body 120 is hooked to the other end of the outer body 110 (see FIGS. 1 and 3). Accordingly, the first inner body 120 can be stably restored by the first lost motion spring 150.

The latching pinhole 129 is inserted into the first inner body 120 such that the fixing member functioning to selectively fix the first inner body 120 to the outer body 110 is inserted, 120 at the other end. In FIGS. 4 and 5, the fastening members are shown as first and second latching pins 170 and 180, which are typical latching pins, but are not limited thereto. The first ratchet pin 170 is operated by hydraulic pressure and may be provided on the other end side of the outer body 110 to easily receive the hydraulic pressure.

The first guide hole 172 is formed at the other end of the outer body 110 to guide the piston movement of the first ratchet pin 170. The first guide hole 172 is formed on one end side of the first latched pin 170 at the other end side of the outer body 110 so as to be adjacent to the latching pin hole 129.

The hydraulic pressure supply hole 177 is formed at the other end of the outer body 110 to supply hydraulic pressure to the first ratchet pin 170. The hydraulic pressure supply hole 177 is formed at the other end of the outer body 110 so that the first ratchet pin 170 is pushed toward the first inner body 120 by the supplied hydraulic pressure, And is formed on the other end side of the nicking pin 170. The first ratchet pin 170 is pushed toward the one end of the outer body 110 by the hydraulic pressure supplied through the hydraulic pressure supply hole 177 and the first guide hole 172 of the outer body 110 So that the first inner body 120 is fixed to the outer body 110 by being inserted into the latching pinhole 129 of the first inner body 120. Here, the inner diameter d of the hydraulic pressure supply hole 177 can be set by a person skilled in the art such that the responsiveness of the first latched pin 170 operated by the hydraulic supply is optimized.

The first latching spring 175 is disposed between the first guide hole 172 and the other end of the first latching pin 170 to return the first latching pin 170 to a position before being pushed by the hydraulic pressure Respectively. That is, when the hydraulic pressure supplied through the hydraulic pressure supply hole 177 is released, the first latching pin 170 is retracted by the first latching spring 175, so that the first inner body 120 and the outer The fixing of the body 110 is released.

When the first inner body 120 is fixed to the outer body 110, a high lift of the valve is performed by the outer body 110 leaning with the first inner body 120 .

5 is a cross-sectional view taken along the line B-B in Fig. 5 is a view illustrating a configuration for selectively fixing the second inner body 130 to the outer body 110. As shown in FIG.

5, the second inner body 130 further includes a stopper 136 and a latching pinhole 139. The outer body 110 is provided with a second ratchet pin 180, A hole 182, a second latching spring 185, and a hydraulic chamber 187 are further formed or equipped.

The stopper 136 is formed protruding from the other end of the second inner body 130. When the second inner body 130 reaches the original position by the second lost motion spring 151, And the other end of the inner body 130 is hooked to the other end of the outer body 110 (see FIGS. 1 and 3). Therefore, the second inner body 130 can be stably restored by the second lost motion spring 151.

The latching pinhole 139 is a hole formed at the other end of the second inner body 130 so that the second latching pin 180 is inserted. The second ratchet pin 180 is operated by hydraulic pressure and may be provided on the other end side of the outer body 110 to easily receive the hydraulic pressure.

The second guide hole 182 is formed at the other end of the outer body 110 to guide the piston movement of the second ratchet pin 180. The second guide hole 182 is formed on one end side of the second latched pin 180 at the other end side of the outer body 110 so as to be adjacent to the latching pin hole 139.

The second lathe pin 180 is inserted into the latching pin hole 139 by the elastic force of the second latching spring 185 so that the second inner body 130 can be fixed to the outer body 110 . That is, the second latching spring 185 is provided at the other end of the second latching pin 180 so that one end of the second latching spring 185 pushes the second latching pin 180 toward the second inner body 130. A hydraulic chamber 187 surrounded by the outer body 110 and the second latched pin 180 is formed at one end of the second latched pin 180. The second ratchet pin 180 is pushed toward the other end of the outer body 110 by the hydraulic pressure supplied to the hydraulic chamber 187 so that the second inner body 130 and the outer body 110 can be rotated, Is released. In other words, when the hydraulic pressure supplied to the hydraulic chamber 187 is released, the second latching pin 180 passes through the second guide hole 182 by the second latching spring 185, The second inner body 130 is fixed to the outer body 110 by being inserted into the pinhole 139.

When the second inner body 130 is fixed to the outer body 110, the normal lift of the valve is moved by the outer body 110, which moves together with the second inner body 130, Can be implemented. At this time, when the fixing of the first inner body 120 and the outer body 110 is released, a normal lift of the valve is realized. When the fixing of the first inner body 120 and the outer body 110 and the fixing of the second inner body 130 and the outer body 110 are both released, A zero lift of the valve is implemented by not exercising.

6 is a plan view of a two-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.

6, the two-stage variable valve lift apparatus 200 according to the embodiment of the present invention includes an outer body 210, an inner body 220, a roller 230, a connecting shaft 240, And a motion spring 250.

The outer body 210 selectively receives the rotational force of the cam shafts 10 and 20 and performs a lever motion and operates to open or close the intake valve 40 or the exhaust valve 50. The cams 30 and 30 are formed on the camshafts 10 and 20 so as to convert rotational motion of the camshafts 10 and 20 into lever movement of the outer body 210. Further, a space 212 through which the outer body 210 is vertically penetrated is formed on the inner side of the outer body 210. That is, the outer body 210 has a predetermined length and has a predetermined width and thickness to form an inner space 212 of the outer body 210.

The valve (40, 50) is connected to one end of the outer body (210), and a lever motion rotation shaft is provided at the other end. Also, since the inner space 212 of the outer body 210 is opened to one end side of the outer body 210, the overall shape of the outer body 210 may be formed in a U-shape.

In the following description, one end and the other end of the components provided to or connected to the outer body 210 refer to a part of the outer body 210 in the same direction as the one end and the other end, respectively.

The inner body 220 is disposed in the inner space 112 of the outer body 210. One end of the inner body 220 is rotatably connected to one end of the outer body 210. Further, the inner body 220 receives the rotational force of the cam shaft and performs a lever motion, and is operated to selectively open and close the valves 40 and 50. Further, a space penetrating in the vertical direction is formed inside the inner body 220. That is, the inner body 220 has a predetermined length and has a predetermined width and thickness to form an inner space 224 of the inner body 220.

The roller 230 is disposed in the inner space 224 of the inner body 220. The roller 230 is rotatably connected to the inner body 220. Meanwhile, a roller rotation shaft 235 is provided to rotatably connect the roller 230 and the inner body 220. That is, the roller 230 rotates about the roller rotation shaft 235. The roller 230 is in rolling contact with the cam 30 so as to convert rotational movement of the camshaft 10 and 20 into lever movement of the outer body 210 or the inner body 220.

The connection shaft 240 is rotatably connected to one end of the outer body 210 and one end of the inner body 220. That is, the inner body 220 may rotate relative to the outer body 210 about the connecting shaft 240. One end of the outer body 210 connected to the inner body 20 by the connecting shaft 240 is referred to as an outer connecting part 214 and the outer connecting part 214 is connected to the outer body 210 by the connecting shaft 240. [ One end of the inner body 220 connected with the inner connection part 22 will be referred to as an inner connection part 22.

A valve abutting portion 216 is formed at one end of the outer body 210 adjacent to the outer connecting portion 214. Two outer connecting portions 214 may be formed at one end of the outer body 210 opened to the one end. Accordingly, the valve abutment portion 216 may be formed adjacent to the two outer connection portions 214, or may have two valve abutment portions 216 formed thereon. The valve contact portion 216 is in contact with the valves 40 and 50 and functions to push the two intake valves 40 or the two exhaust valves 50 according to the lever movement of the outer body 210 do.

The inner body 220 is selectively fixed to the outer body 210, and the inner body 220 can be lever-operated, or selectively disengaged, so that the inner body 220 can be independently lever-operated.

The lost motion spring 250 is rotated by the independent lever movement when the fixing of the inner body 220 fixed to the outer body 210 is released and the inner body 220 relatively rotated with the outer body 210 220).

7 is a side cross-sectional view of a two-stage variable valve lift apparatus applied to a cylinder dumped engine according to an embodiment of the present invention.

7, the inner body 220 further includes a latching pinhole 229. A ratchet pin 260, a stopper 267, and a latching spring 265 are attached to the outer body 210, Respectively.

The latching pinhole 229 is a hole to which the latching pin 260 is inserted. The ratchet pin 260 is operated by hydraulic pressure and may be provided at the other end side of the outer body 210 to easily receive the hydraulic pressure. Meanwhile, a member 290 for supplying hydraulic pressure like the HLA can be mounted on the other end side of the outer body 210.

The stopper 267 is provided to prevent the ratchet pin 260 from being separated from the other end of the outer body 210.

The latching pin 260 is inserted into the latching pinhole 229 by the elastic force of the latching spring 265 so that the inner body 220 can be fixed to the outer body 210. That is, the latching spring 265 is a spring provided between the stopper 267 and the latching pin 260 so that one end of the latching spring 265 pushes the latching pin 260 toward the inner body 220. A hydraulic chamber 269 surrounded by the outer body 210 and the latching pin 260 is formed at one end of the latching pin 260. Further, the latching pin 260 is pushed toward the other end of the outer body 210 by the hydraulic pressure supplied to the hydraulic chamber 269, so that the fixing of the inner body 220 and the outer body 210 is released do. In other words, when the hydraulic pressure supplied to the hydraulic chamber 269 is released, the latching pin 260 is retracted into the latching pinhole 229 by the latching spring 265, Is fixed to the outer body 210.

The two-stage variable valve lift apparatus 200 according to the embodiment of the present invention is configured to selectively implement a two-stage lift including a normal lift and a zero lift of the valves 40 and 50 Or a two-stage lift including a high lift and a normal lift of the valves 40,50.

When the two-stage variable valve lift apparatus 200 operates to realize the high lift or the normal lift of the valves 40 and 50, when the hydraulic pressure is supplied to the hydraulic chamber 269, the inner body 220 The latching spring 265 and the hydraulic chamber 269 are reversed with respect to the latching pin 260 so that the latching spring 265 is fixed to the outer body 210, The design can be changed so as to function as a return spring for returning the latching pin 260 to the original position.

A case where the two-stage variable valve lift apparatus 200 selectively implements a normal lift or a zero lift will be described below.

When the inner body 220 is fixed to the outer body 210, the inner body 220 and the outer body 210 are rotated by the rotation of the cam 30 in a rolling contact with the roller 230, And moves together with the outer body 210 about the rotational axis of the lever motion. When the inner body 220 fixed to the outer body 210 is released from rotation, only the inner body 220 is rotated by the rotation of the roller 230, And performs a lever movement around the axis 240.

Here, the normal lift of the valves 40 and 50 is realized by the outer body 210 that performs the lever motion together with the inner body 220, and when the inner body 220 is not lever-operated A zero lift of the valve 40, 50 for performing the cylinder pause by the outer body 110 can be realized.

A case in which the two-stage variable valve lift apparatus 200 selectively implements a high lift or a normal lift will be described below.

When the inner body 220 is fixed to the outer body 210, the inner body 220 and the outer body 210 are rotated by the rotation of the cam 30 in a rolling contact with the roller 230, And moves together with the outer body 210 about the rotational axis of the lever motion. When the inner body 220 fixed to the outer body 210 is released from rotation, the inner body 220 is rotated by the rotation of the roller 230 in a rolling contact with the roller 230, The outer body 210 is restrained by the inner body 220 having a certain degree of lever movement around the connecting shaft 240 and the lever 240 of the outer body 210 Move the lever about the rotation axis.

Here, the high lift of the valve is realized by the outer body 210 that levers with the inner body 220, and the inner body 220, which is somewhat lever-moved around the connecting shaft 40, The normal lift of the valve can be realized by the outer body 210 that is constrained to the lever motion and moves in the lever motion.

9 is a block diagram showing the supply of hydraulic pressure for implementing the four drive modes of the cylinder idle engine according to the embodiment of the present invention, 1 is a schematic view of an oil gallery according to an embodiment of the present invention.

Although the four-cylinder engine is shown in Figs. 8 to 10, the embodiment of the present invention is not limited thereto. 8 and 10 show the first cylinder Cyl 1, the second cylinder Cyl 2, the third cylinder Cyl 3 and the fourth cylinder Cyl 4 and the intake side of the engine Intake And the exhaust side are shown by a one-dot chain line.

Herein, the cylinder in which the pause is selectively performed is referred to as a pause cylinder (Cyl 2, 3), and the cylinder in which pause is not performed is referred to as non-pause cylinder (Cyl 1, 4). 8 to 10, the second cylinder Cyl 2 and the third cylinder Cyl 3, which are normally in a rest state in the four-cylinder engine, are shown as rest cylinders Cyl 2 and 3, The first cylinder Cyl 1 and the fourth cylinder Cyl 4 which are not realized are shown as the non-resting cylinders Cyl 1 and Cyl 4, but are not limited thereto.

8, the cylinder diesel engine according to the embodiment of the present invention includes the three-stage variable valve lift apparatus 100, the two-stage variable valve lift apparatus 200, the valve opening / closing apparatus 300, And a gallery 710, 720.

The three-stage variable valve lift apparatus 100 is configured to move the second cylinder (Cyl 2) and the second cylinder (Cyl 2) from the intake side (Intake) so as to open and close the intake valve (40) of the damping cylinders And the third cylinder Cyl 3, respectively. The three-stage variable valve lift apparatus 100 is also operated to selectively implement one of zero lift, normal lift, and high lift of the idle cylinders (Cyl 2, 3) intake valves 40.

The two-stage variable valve lift apparatus 200 is configured so as to open and close the exhaust valve 50 of the damping cylinders Cyl 2 and 3 by lever movement, (Cyl 1) and the fourth cylinder (Cyl 3) at the intake side (Intake) so as to open and close the intake valves (40) of the non-idle cylinders Respectively, in the cylinder Cyl 4. The two-stage variable valve lift apparatus 200 disposed at the exhaust side of the dormant cylinders Cyl 2 and Cylinder 3 is connected to the zero lift and normal of the exhaust valves 50 of the dormant cylinders Cyl 2 and 3 Wherein the two-stage variable valve lift apparatus 200 disposed on the intake side (Intake) of the non-resting cylinders Cyl 1, 4 is operated to selectively implement one of the non-resting cylinders Cyl 1, 4 ) Of the intake valve 40 to selectively implement one of the normal lift and the high lift.

The valve opening and closing device 300 is configured to open and close the exhaust valve 50 of the non-resting cylinders Cyl 1 and 4 by connecting the first cylinder Cyl 1 and the fourth cylinder Cyl 4 Respectively. In addition, the valve opening / closing apparatus 300 functions to realize a constant single lift of the non-resting cylinder (Cyl 1, 4) exhaust valve 50. That is, the exhaust valve 50 of the non-resting cylinders Cyl 1, 4 is always operated as a normal lift. The valve opening / closing device 300 may be a conventional rocker arm that opens and closes one valve 50, or a rocker arm that simultaneously opens and closes two valves 50.

The oil galleries 710 and 720 include an intake oil gallery 710 and an exhaust oil gallery 720. Meanwhile, it is obvious to those skilled in the art that oil galleries 710 and 720, which are oil passages for transmitting oil to respective parts, are provided in the cylinder block or the cylinder head of the engine, so that detailed description thereof will be omitted.

The intake air gallery 710 is connected to the three-stage variable valve lift apparatus 100 disposed on the intake side of the damping cylinders Cyl 2 and 3 and the intake side of the non-dung cylinders Cyl 1 and Cyl 4 Stage variable valve lift apparatus 200 arranged in the second intake valve (Intake).

The exhaust oil gallery 720 is provided to supply oil to the two-stage variable valve lift apparatus 200 disposed on the exhaust side of the dirty cylinders Cyl 2, 3.

9, the cylinder diesel engine according to the embodiment of the present invention includes an oil pump 400, an oil control valve (OCV) 500, a controller 600, and oil supply passages 60, 70, 80, 90). Further, the camshafts 10, 20 are formed into a hollow cylindrical shape.

The oil pump 400 pumps the oil to generate the hydraulic pressure required to operate the three-stage variable valve lift apparatus 100 and the two-stage variable valve lift apparatus 200. The oil pump 400 is operated by receiving the rotational force of a crankshaft (not shown) of the engine. Since the oil pump 400 is obvious to those skilled in the art, a detailed description thereof will be omitted.

The oil control valve 500 controls the hydraulic pressure delivered from the oil pump 400 to be selectively supplied to the three-stage variable valve lift apparatus 100 and the two-stage variable valve lift apparatus 200. The construction of the oil control valve 500 may vary depending on the design of a person skilled in the art, and the construction of the general oil control valve 500 will be apparent to those skilled in the art, and thus a detailed description thereof will be omitted.

The oil control valve 500 includes at least four oil control valves 500 to implement four drive modes of the cylinder idle engine. Here, the four oil control valves 500 are referred to as a first oil control valve 510, a second oil control valve 520, a third oil control valve 530, and a fourth oil control valve 540 .

The controller 600 is connected to the oil control valve 500 to control opening and closing of the oil control valve 500. Here, the oil control valve 500 is electrically operated, and the controller 600 may be a conventional electronic control unit (ECU) that controls the control of the electronic devices of the automobile.

The oil supply passages 60, 70, 80 and 90 are oil passages for supplying hydraulic pressure to operate the three-stage variable valve lift apparatus 100 and the two-stage variable valve lift apparatus 200. [ The oil supply passages 60, 70, 80, and 90 may include a first oil supply passage 60 communicating with the first oil control valve 510, a second oil supply passage 60 communicating with the second oil control valve 520, A third oil supply passage 80 communicating with the third oil control valve 530 and a fourth oil supply passage 90 communicating with the fourth oil control valve 540, .

The first oil supply passage 60 is connected to the three-stage variable valve lift apparatus 100 disposed on the intake side (Intake) of the second cylinder Cyl 2 and the third cylinder Cyl 3, And communicates with the intake air gallery 710 through the hollow of the intake camshaft 10 to supply the intake air.

Here, the first oil supply passage 60 is branched into two bifurcations in the hollow of the intake camshaft 10. The one branched first oil supply passage 60 is connected to one HLA 190 of the three-stage variable valve lift apparatus 100 disposed on the intake side (Intake) of the second cylinder Cyl 2, To the intake oil gallery 710 at a point I2 adjacent to the intake air gallery 710. [ The other branched first oil supply passage 60 is connected to one HLA 190 of the three-stage variable valve lift apparatus 100 disposed at the intake side (Intake) of the third cylinder Cyl 3 To the intake oil gallery 710 at a point I4 adjacent to the intake air gallery 710. [

That is, when the controller 600 opens the first oil control valve 510, the oil pumped from the oil pump 400 flows through the first oil supply passage 60 to the second cylinder Cyl Stage variable valve lift apparatus 100 arranged on the intake side (Intake) of the third cylinder (Cyl 3) arranged on the intake side (Intake) of the third cylinder (Cyl 3) And is supplied to one HLA 190 of the valve lift apparatus 100. The hydraulic pressure supplied to the three-stage variable valve lift apparatus 100 through the first oil supply passage 60 is set to a high lift of the second and third cylinder (Cyl 2, 3) intake valves 40 The three-stage variable valve lift apparatus 100 is operated.

The second oil supply passage 70 is connected to the two-stage variable valve lift apparatus 200 disposed on the intake side (Intake) of the first cylinder Cyl 1 and the fourth cylinder Cyl 4, And communicates with the intake air gallery 710 through the hollow of the intake camshaft 10 to supply the intake air.

Here, the second oil supply passage 70 is diverged from the hollow of the intake camshaft 10 in two directions. The one branched second oil supply passage 70 is disposed adjacent to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed on the intake side (Intake) of the first cylinder Cyl 1 And communicates with the intake air gallery 710 at point I1. Further, the other branched second oil supply passage 70 is connected to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed on the intake side (Intake) of the fourth cylinder Cyl 4 And communicates with the intake oil gallery 710 at an adjacent point I6.

That is, when the controller 600 opens the second oil control valve 520, the oil pumped from the oil pump 400 flows through the second oil supply passage 70 to the first cylinder Cyl 1 and the HLA 290 of the two-stage variable valve lift apparatus 200 disposed on the intake side (Intake) of the fourth cylinder Cyl 4, respectively. The hydraulic pressure supplied to the two-stage variable valve lift apparatus 200 through the second oil supply passage 70 is a high lift of the first and fourth cylinder intake valves 40 The two-stage variable valve lift apparatus 200 is operated.

The third oil supply passage 80 is branched into two branches and one of them branches the oil pressure to the three-stage variable valve lift apparatus 100 disposed on the intake side (Intake) of the second cylinder Cyl 2 And the other branch is communicated to the intake air gallery 710 through the hollow of the intake camshaft 10 so as to be communicated with the two-stage variable valve disposed at the exhaust side of the second cylinder Cyl 2, And communicates with the exhaust oil gallery 720 through the hollow of the exhaust cam shaft 20 to supply hydraulic pressure to the lift apparatus 200. [

The branched one third oil supply passage 80 is connected to the other HLA 190 of the three-stage variable valve lift apparatus 100 disposed at the intake side (Intake) of the second cylinder Cyl 2 To the intake air gallery 710 at a point I3 adjacent to the intake air gallery 710. [ The other branched third oil supply passage 80 is connected to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed at the exhaust side of the second cylinder Cyl 2 And communicates with the exhaust oil gallery 720 at an adjacent point E1.

That is, when the controller 600 opens the third oil control valve 530, the oil pumped from the oil pump 400 flows through the third oil supply passage 80 to the second cylinder Cyl Stage variable valve lift apparatus 100 arranged on the intake side of the second cylinder Cyl 2 and the second stage HLA 190 disposed on the exhaust side of the second cylinder Cyl 2 of the three- Is supplied to the HLA (290) of the variable valve lift apparatus (200). The hydraulic pressure supplied to the three-stage variable valve lift apparatus 100 through the third oil supply passage 80 is supplied to the third cylinder Cyl 2 intake valve 40 to implement the zero- The variable valve lift apparatus 100 is operated so that the hydraulic pressure supplied to the two-stage variable valve lift apparatus 200 is transmitted to the second-stage variable valve lift apparatus 100 so as to realize the zero-lift of the second cylinder (Cyl 2) The lift apparatus 200 is operated.

The fourth oil supply passage 90 is divided into two branches and one branch is supplied with hydraulic pressure to the three-stage variable valve lift apparatus 100 disposed on the intake side of the third cylinder Cyl 3 And the other branch is communicated to the intake air gallery 710 through the hollow of the intake camshaft 10 so as to be communicated with the two-stage variable valve disposed at the exhaust side of the third cylinder Cyl 3, And communicates with the exhaust oil gallery 720 through the hollow of the exhaust cam shaft 20 to supply hydraulic pressure to the lift apparatus 200. [

The branched one fourth oil supply passage 90 is connected to the other HLA 190 of the three-stage variable valve lift apparatus 100 disposed on the intake side (Intake) of the third cylinder Cyl 3 To the intake oil gallery 710 at a point I5 adjacent to the intake air gallery 710. [ The other branched fourth oil supply passage 90 is connected to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed at the exhaust side of the third cylinder Cyl 3 And communicates with the exhaust oil gallery 720 at an adjacent point E2.

That is, when the controller 600 opens the fourth oil control valve 540, the oil pumped from the oil pump 400 is supplied to the third cylinder Cyl Stage variable valve lift apparatus 100 disposed on the intake side of the third cylinder Cyl 3 and the second stage HLA 190 disposed on the exhaust side of the third cylinder Cyl 3, Is supplied to the HLA (290) of the variable valve lift apparatus (200). The hydraulic pressure supplied to the third-stage variable valve lift apparatus 100 through the fourth oil supply passage 90 is supplied to the third-stage variable valve lift apparatus 100 to implement the zero-lift of the third cylinder (Cyl 3) And the hydraulic pressure supplied to the two-stage variable valve lift apparatus 200 is supplied to the second-stage variable valve lift apparatus 100 to implement the zero-lift of the third cylinder (Cyl 3) The lift apparatus 200 is operated.

In the meantime, the three-stage variable valve lift apparatus 100 and the two-stage variable valve lift apparatus 200 provided in the cylinder diesel engine according to the embodiment of the present invention are arranged such that when the hydraulic pressure is not supplied, And is operated to implement a normal lift.

9 and 10, a diaphragm 730 is provided on the intake oil gallery 710 and the exhaust oil gallery 720. The intake air gallery 710 is connected to the three-stage variable valve lift apparatus 100 disposed on the intake side of the first, second, third and fourth cylinders Cyl 1, 2, 3 and 4, (190, 290) of the two-stage variable valve lift apparatus (200). Further, the exhaust oil gallery 720 is provided with the HLA (290) of the two-stage variable valve lift apparatus 200 disposed at the exhaust side of the second and third cylinders (Cyl 2, 3) do.

The diaphragm 730 is connected to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed in the first cylinder Cyl 1 in the intake air gallery 710, The first HLA 190 of the three-stage variable valve lift apparatus 100 disposed in the second cylinder Cyl 2 and the first HLA 190 disposed adjacent to the first HLA 190 disposed in the second cylinder Cyl 2, A region in which a point I2 communicating with the oil supply passage 60 is disposed, a region adjacent to the other HLA 190 of the three-stage variable valve lift apparatus 100 disposed in the second cylinder Cyl2, The first HLA 190 of the three-stage variable valve lift apparatus 100 disposed in the third cylinder Cyl 3 is disposed in a region where a point I3 communicating with the third oil supply passage 80 is disposed, And a region (I4) communicating with the first oil supply passage (60) adjacent to the third cylinder (Cyl3) An area in which the other HLA 190 of the valve lift device 100 and the point I5 adjacent to the HLA 190 and communicated with the fourth oil supply passage 90 are disposed, An HLA (290) of the two-stage variable valve lift apparatus (200) disposed adjacent to the second oil supply passage (70) and a region (I2) communicating with the second oil supply passage (70) are disposed. That is, at least five diaphragms 730 are provided in the intake air gallery 710.

The diaphragm 730 is connected to the HLA 290 of the two-stage variable valve lift apparatus 200 disposed in the second cylinder Cyl 2 at the exhaust oil gallery 710, (H1) of the two-stage variable valve lift apparatus (200) disposed in the third cylinder (Cyl3), and a region (E1) communicating with the fourth oil And a region where a point E2 communicating with the supply passage 90 is disposed. That is, at least one diaphragm 730 is provided in the exhaust oil gallery 720.

Referring to FIG. 10, the intake air gallery 710 and the exhaust oil gallery 710 are formed along one straight line.

I 2, I 3, I 4, I 5, I 6, I 4, I 6, I 4, I 6, I 3, I 4, I 6, The intake oil gallery 710 and the exhaust oil gallery 710 are formed along one straight line by communicating with the intake oil gallery 710 and the exhaust oil gallery 710 respectively at the intake oil gallery 710 and the exhaust oil gallery 710 It is possible. Therefore, the HLA 190 mounted on the three-stage variable valve lift apparatus 100 and the HLA mounted on the two-stage variable valve lift apparatus 200 may be the same.

In other words, the three-stage variable valve lift apparatus 100 and the two-stage variable valve lift apparatus 200 are provided with a hole H communicating with the intake air gallery 710 and the exhaust oil gallery 710 It is possible to apply the HLA 190, 290 formed at the same position. Therefore, by applying the standardized HLA (190, 290) according to the engine, the production efficiency can be improved.

Hereinafter, referring to FIG. 11, the four drive modes of the engine will be divided into first, second, third, and fourth modes.

11 is a table showing four drive modes of the cylinder idle engine according to the embodiment of the present invention.

According to the table shown in FIG. 11, the engine mode of the engine implemented according to the selective opening and closing of the first, second, third, and fourth oil control valves 510, 520, 530, It is different.

The first mode (Mode 1) is implemented by closing all of the first, second, third, and fourth oil control valves 510, 520, 530, and 540. At this time, the valves 40, 50 of all the cylinders Cyl 1, 2, 3, 4, including the exhaust valves 50 of the first and fourth cylinders Cyl 1, 4, It operates as a normal lift.

In the second mode (Mode 2), the first and second oil control valves 510 and 520 are closed and the third and fourth oil control valves 530 and 540 are opened. At this time, the intake valves 40 and the exhaust valves 50 of the second and third cylinders Cyl 2 and 3 are operated as zero lift and the intake valves 40 of the first and fourth cylinders Cyl 1 and Cyl 4 40) operate as a normal lift. That is, the idle cylinders Cyl 2, 3 are stopped and the non-idle cylinders Cyl 1, 4 are maintained in the normal lift driving.

In the third mode (Mode 3), the first oil control valve 510 is closed and the second, third and fourth oil control valves 520, 530 and 540 are opened. At this time, the intake valves 40 and the exhaust valves 50 of the second and third cylinders Cyl 2 and 3 are operated as zero lift and the intake valves 40 of the first and fourth cylinders Cyl 1 and Cyl 4 40 operate as a high lift. That is, the idle cylinders Cyl 2 and 3 are stopped, and the non-idle cylinders Cyl 1 and 4 are driven by high lift. Further, the high-lift driving of the intake valve 40 increases the valve opening / closing time according to the normal valve profile, and the energy of the piston (not shown) driven by the retarding of the advancing and closing of the opening of the intake valve 40 Atkinson Engine Cycle for reducing the loss can be implemented in the first and fourth cylinders (Cyl 1, 4).

In the fourth mode (Mode 4), the first and second oil control valves 510 and 520 are opened and the third and fourth oil control valves 530 and 540 are closed. At this time, the intake valves 40 of all the cylinders Cyl 1, 2, 3, 4 are operated at a high lift. Furthermore, the atkinson cycle may be implemented in all cylinders (Cyl 1, 2, 3, 4).

As described above, according to the embodiment of the present invention, it is possible to realize variable valve lift of all the cylinders while implementing the rest of the rest cylinder. Further, by implementing four modes of engine driving by the four oil control valves, it is possible to efficiently drive the engine according to the state of the engine and the running state of the vehicle. Further, the construction of the oil gallery 710, 720 for implementing the cylinder stop and the variable valve lift can be simplified. Thus, ultimately, the improvement of fuel economy can be maximized and the productivity can be increased.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And all changes to the scope that are deemed to be valid.

10: intake camshaft 20: exhaust camshaft
30: Cam
40: intake valve 50: exhaust valve
60, 70, 80, 90: first, second, third and fourth oil supply passages
100: Three-stage variable valve lift device
110: outer body 111:
112: first inner space 113: second inner space
114: outer connection part 115: first seat groove
116: valve contact portion 117: second seat groove
120: first inner body 124: inner body inner space
126: Stopper 129: latching pinhole
130: second inner body 136: stopper
139: latching pinhole
140: connection axis
150: first lost motion spring
151: second lost motion spring
152, 153: outer fixing part 154, 155: inner fixing part
160: roller 165: roller rotation axis
170: first latch pin 172: first guide hole
175: first latching spring 177: hydraulic pressure supply hole
180: second latching pin 182: second guide hole
185: second latching spring 187: hydraulic chamber
200: Two-stage variable valve lift device
210: outer body 212: outer body inner space
214: outer connection part 216: valve contact part
220: Inner body 222: Inner connection
224: inner body inner space 229: latching pinhole
230: roller 235: roller rotation shaft
240: Connecting axis 250: Lost motion spring
260: latching pin 265: latching spring
267: Stopper 269: Hydraulic chamber
300: valve opening / closing device 400: oil pump
500: Oil control valve
510, 520, 530, 540: 1st, 2nd, 3rd, 4th oil control valve
600: controller
710: Intake Oil Gallery 720: Exhaust Oil Gallery
730: diaphragm

Claims (15)

CLAIMS What is claimed is: 1. A cylinder diesel engine comprising at least two cylinders,
At least one dormant cylinder in which dormancy is selectively performed;
At least one non-dormant cylinder in which no dwell is performed;
A three-stage variable valve lift device provided on an intake side of the dormant cylinder and operated to realize a lift of the valve as one of three lifts;
A two-stage variable valve lift device provided on an exhaust side of the dormant cylinder and an intake side of the non-dormant cylinder, the two-stage variable valve lift device being operated to implement the lift of the valve in one of two lifts;
An oil pump for generating a hydraulic pressure for operating the three-stage variable valve lift apparatus and the two-stage variable valve lift apparatus;
A plurality of oil control valves operable to selectively supply oil pressure generated from the oil pump to the three-stage variable valve lift device and the two-stage variable valve lift device, respectively;
An intake oil gallery passing through both the pivot shaft of the three-stage variable valve lift device and the pivot axis of the two-stage variable valve lift device provided on the intake side of the non-idle cylinder;
An exhaust oil gallery passing through all of the pivot shafts of the two-stage variable valve lift device provided at the exhaust side of the dormant cylinder; And
A plurality of oil supply passages communicating the intake oil gallery and the exhaust oil gallery with the plurality of oil control valves;
, ≪ / RTI &
Said oil control valve comprising first, second, third and fourth oil control valves,
Four drive modes are implemented according to opening and closing of the first, second, third and fourth oil control valves,
In the four drive modes,
A first mode in which all the valves of the dormant cylinder and the non-dormant cylinder are operated as a normal lift;
A second mode in which the intake valve and the exhaust valve of the idle cylinder are operated as a zero lift, and the intake valve of the non-idle cylinder is operated as a normal lift;
A third mode in which the intake valve and the exhaust valve of the idle cylinder are operated as a zero lift and the intake valves of the non-idle cylinder are operated as a high lift; And
A fourth mode in which all the valves of the dormant cylinder and the non-dormant cylinder are operated as a high lift;
And the engine is stopped. The method according to claim 1,
The three valve lifts implemented by the three-stage variable valve lift apparatus are a zero lift, a normal lift, and a high lift,
Wherein the three-stage variable valve lift apparatus is operated by hydraulic pressure to implement a normal lift or a high lift. The method according to claim 1,
The two valve lifts implemented by the two-stage variable valve lift apparatus disposed on the exhaust side of the idle cylinder are a zero lift and a normal lift,
Wherein the two-stage variable valve lift apparatus is operated by hydraulic pressure to implement a zero-lift. The method according to claim 1,
The two valve lifts implemented by the two-stage variable valve lift apparatus disposed on the intake side of the non-idle cylinder are a normal lift and a high lift,
Wherein the two-stage variable valve lift apparatus is actuated by hydraulic pressure to implement a high lift. The method according to claim 1,
Wherein the intake air gallery and the exhaust oil gallery are formed along one straight line, respectively. delete The method according to claim 1,
Wherein the plurality of oil supply passages
A first oil supply passage communicating the intake oil gallery and the first oil control valve to supply a hydraulic pressure to one pivot shaft of the three-stage variable valve lift apparatus;
A second oil supply passage communicating the intake oil gallery and the second oil control valve to supply hydraulic pressure to a pivot shaft of a two-stage variable valve lift device disposed on an intake side of the non-idle cylinder; And
The exhaust oil gallery and the third oil control valve are communicated with each other to supply hydraulic pressure to the pivot shaft of the two-stage variable valve lift apparatus disposed on the exhaust side of the damping cylinder and the other pivot shaft of the three-stage variable valve lift apparatus A third oil supply passage;
And a cylinder braking engine. 8. The method of claim 7,
When the number of the idle cylinders is two,
Wherein the first oil supply passage communicated with the first oil control valve branches in two directions to supply hydraulic pressure to each one of the pivot shafts of the three-stage variable valve lift device disposed in the two idle cylinders, In connection with the gallery,
Wherein the plurality of oil supply passages are connected to a pivot shaft of a two-stage variable valve-lifting device disposed on an exhaust side of another idle cylinder and a pivot shaft of another one of the three-stage variable valve- Further comprising a fourth oil supply passage communicating with the exhaust oil gallery and the fourth oil control valve to supply the exhaust oil gallery and the fourth oil control valve. 8. The method of claim 7,
Further comprising a cam shaft formed into a hollow cylindrical shape,
And the plurality of oil supply passages communicate with the intake air gallery and the exhaust oil gallery through the hollow of the camshaft. delete The method according to claim 1,
The first mode is implemented by closing all of the first, second, third and fourth oil control valves,
The second mode is implemented by closing the first and second oil control valves and opening the third and fourth oil control valves,
The third mode being implemented by closing the first oil control valve and opening the second, third and fourth oil control valves,
Wherein the fourth mode is implemented by opening the first and second oil control valves and closing the third and fourth oil control valves. The method according to claim 1,
Wherein in the intake air gallery, each portion through which the plurality of oil supply passages communicate is partitioned by a diaphragm. 13. The method of claim 12,
Wherein in the exhaust oil gallery, each portion through which the plurality of oil supply passages communicate is partitioned by a diaphragm. 9. The method of claim 8,
Wherein the at least two cylinders include first, second, third and fourth cylinders, wherein the first and fourth cylinders are non-dormant cylinders, and the second and third cylinders are dormant cylinders.
Wherein the intake oil gallery has a region communicating with the second oil supply passage from the side of the first cylinder, a region communicating with the first oil supply passage from the side of the second cylinder, A region communicating with the first oil supply passage at the second cylinder side, a region communicating with the supply passage, a region communicating with the first oil supply passage at the third cylinder side, a region communicating with the fourth oil supply passage at the third cylinder side, And a region communicated with the second oil supply passage is partitioned by the diaphragm. 15. The method of claim 14,
Wherein the exhaust oil gallery is partitioned by a diaphragm in a region communicating with the third oil supply passage from the second cylinder side and a region communicating with the fourth oil supply passage from the third cylinder side. Dormant engine.

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