KR20040051623A - Delivery apparatus for blow-by gas - Google Patents

Abstract

PURPOSE: A device for distributing blow-by gas is provided to stabilize the combustion characteristics of an engine by uniformly distributing the blow-by gas generated in combustion to respective cylinders by recirculating the gas to an intake manifold. CONSTITUTION: A connecting passage(41) for guiding the flow of blow-by gas is formed in the lower portion of a center shell(30b). A partition wall(42) is additively formed from a nipple(40) to the connecting passage to make the blow-by gas flowing into the connecting passage flow into runners(31,34) after flowing into other runners(32,33) in the middle. The blow-by gas entering through the nipple is guided to a specific position of the connecting passage and spread to both sides of the connecting passage. Then, the blow-by gas flows into the runners.

Description

Delivery apparatus for blow-by gas

The present invention relates to a distribution device of blow-by gas, and more particularly, to recycle the blow-by gas generated in the combustion process of the engine to the intake manifold so that the combustion characteristics of the engine can be stabilized evenly. It relates to a distribution device of blow-by gas for.

In general, while the engine of the vehicle is in operation, combustion gas and unburned gas generated during the explosion stroke of the engine leak into the crankcase through a gap between the piston and the cylinder liner. This is called blow-by gas.

As a result, the oil becomes thin or deteriorated by the influence of heat, moisture of combustion gas, fuel, etc., and sludge is formed. To prevent this, a ventilator called a breather is installed in the crankcase and discharged into the atmosphere.

On the other hand, the blow-by gas includes a hydrocarbon (HC), which is a source of air pollution, so that a blow-by gas recirculation apparatus forcibly introduced into the intake system and sent to the combustion chamber for combustion is provided.

In order to recycle the blow-by gas, conventionally, the blow-by gas generated at the cylinder block side is guided into the head cover of the upper part of the engine through a passage provided at one side of the engine, so that oil is separated. The oil separated from the head cover is returned to the oil pan, and the gas from which the oil is removed is led to the combustion chamber of the engine and reburned. A positive crankcase ventilation valve (PCV) valve is formed at one side of the cylinder head cover to guide the blow-by gas separated from the oil component to the combustion chamber, and the PCV valve is opened and closed by a negative pressure according to the operating state of the engine. A method of causing the blow-by gas to be directed to the intake manifold side and to be supplied to the combustion chamber together with the fresh air is mainly used.

Meanwhile, in order to distribute the blow-by gas evenly to each combustion chamber, as shown in FIG. 3, the intake manifold 20 is mounted on one side of the upper part of the cover 12 which covers the upper part of the cylinder head 10. The nipple 15 for connecting the blow-by hose 16 guided from the PCV valve 14 side is formed, and the runner 21 in which the blow-by gas introduced through the nipple 25 is connected to each combustion chamber, Each runner 21, 22, 23, 24 is connected to the connecting passage 26 so that the runners 21, 22, 23, 24 can be guided in the middle of the 22, 23, 24. The connection passage 26 is formed on the lower surface of each runner 21, 22, 23, 24 of the intake manifold 20 as shown in FIG. 5, and each of the runners 21, 22, 23, 24 described above. ) And the distribution hole 27 penetrates at the position where the connection passage 26 intersects with each other, so that the blow-by gas passing through the connection passage 26 can be distributed and introduced into each combustion chamber.

4 illustrates a type of a conventional intake manifold, in which a center shell 20b is coupled to an upper side of a plenum cap shell 20a having a predetermined volume, and the center shell 20 20b) shows a state where the runner cap shell 20c is coupled. The body portion of the center shell 20b covers the upper portion of the plenum cap shell 20a to form a surge tank, and the runner portion of the center shell 20b is coupled with the runner lower side of the runner cap shell 20c to surge It is to guide the air of the tank to the combustion chamber. In particular, the connection passage 26 for passing the blow-by gas is integrally formed under the runner portion of the center shell 20b. 5 is a view for showing the interior of the connection passage 26 described above.

However, in the above-described conventional blow-by gas distribution device, the blow-by gas flowing through the nipple provided on one side of the intake manifold is distributed through the distribution hole which is constantly formed, and thus the distribution hole and the nipple on the side close to the nipple. The amount of blow-by gas distributed through the distribution hole on the far side is severely different. Therefore, since the distribution characteristics of the blow-by gas are not constant between the combustion chambers, the combustion characteristics between the combustion chambers are different from each other, resulting in a difference in explosion pressure, which significantly affects the performance of the engine as well as the noise and vibration. There was this.

Therefore, the present invention has been made to solve the above problems, and by recycling the blow-by gas generated in the combustion process of the engine to the intake manifold side to distribute evenly to each cylinder to stabilize the combustion characteristics of the engine It is an object to provide a distribution device of blow-by gas.

The present invention as a means for achieving the above object,

A blow-by gas is formed at the lower side of the runners formed in the intake manifold so that the blow-by gas is distributed to each combustion chamber and flows therein, and through-holes are formed at the intersections of the runners and the connect-pass passages. In the distribution device of,

The barrier rib is further formed from the nipple to the predetermined position of the connection passage so that the blow-by gas flowing into the connection passage first flows into the runner positioned at the intermediate side and then into the runner positioned at both sides. The blow-by gas introduced through the nipple is guided to a predetermined position of the connection passage, and then spreads to both sides of the connection passage to be introduced into each runner.

1 is a mounting state of the intake manifold according to the present invention.

2 shows a center shell according to the invention;

3 is a state in which a conventional intake manifold is mounted.

4 is a view of a conventional intake manifold.

5 is a view for explaining a conventional blow-by gas connection passage.

※ Explanation of symbols in main part of drawing

10: cylinder head 12: cover

14: PCV valve 14: blow-by gas

30: intake manifold 30b: center shell

31: first runner 32: second runner

33: third runner 34: fourth runner

35,36,37,38: Through hole 40: Nipple

41: connecting hose 42: bulkhead

Hereinafter, a preferred embodiment according to the configuration and operation of the blow-by gas distribution device according to the present invention will be described in detail with the accompanying drawings.

1 is a state diagram of the intake manifold according to the present invention, Figure 2 is a view showing a center shell according to the present invention.

Reference numeral 30, which is formed in the drawing, designates an intake manifold according to the present invention, and reference numeral 30b designates a center cell of the intake manifold according to the present invention, and some reference numerals refer to the prior art for convenience of description. Reference numerals used in the description will be cited as they are.

As described above, the center shell 30b is assembled with a plenum cap shell under the body portion, and the runner cap shell is assembled with the upper side of the runner portion to form a surge tank and a runner.

In particular, the connection passage 41 for guiding the flow of the blow-by gas is formed in the lower portion of the center shell (30b). In addition, the blow-by gas flowing into the connection passage 41 is located at the position where the connection passage 41 and the respective runners 31, 32, 33, 34 cross each runner 31, 32, 33, 34) Through-holes 35, 36, 37, 38 are formed to be introduced into. In particular, the diameters of the through holes 35 and 38 formed in the middle of the first runner 31 and the fourth runner 34 are through holes formed in the middle of the second runner 32 and the third runner 33. It is formed larger than the diameter of (36,37).

And the inside of the connection passage 41, unlike the prior art, blow-by gas input to the nipple 40 side first flows into the through-holes 36 and 37 located in the runners 32 and 33 on the center side, Subsequently, the blow-by gas is introduced into the through holes 35 and 38 positioned in the runners 31 and 34 on both sides. That is, a separate partition wall 42 is formed in the middle of the connection passage 41, that is, from the nipple 40 side to a predetermined position of the connection passage 41, which is a blow input from the nipple 40. By-gas is guided to the middle portion of the connecting passage 41 and then formed to spread to both sides of the connecting passage 41. To this end, a partition wall 42 is formed from a front of the through hole 35 formed in the first runner 31 to a predetermined position of the connection passage 41. In particular, the partition 42 is preferably formed to the middle of the connecting passage 41.

As described above, the size of the through holes 35 and 38 formed in the first runner 31 and the fourth runner 34 is formed in the middle of the second runner 32 and the third runner 33. The reason for forming larger than 37 is because the pressure in the middle portion of the connecting passage 41 is higher than both sides of the connecting passage 41, so that the blows are input to the through holes 35, 36, 37, 38 respectively. This is to make the amount of bi-gas uniform.

Referring to the operation of the present invention configured as described above are as follows.

When the engine is started, blow-by gas is generated by the combustion gas coming down the inner wall of the cylinder to the crankcase side during operation of the engine, the splashing of the engine oil and the evaporation gas of the oil returned from the cylinder head or the like.

The blow-by gas generated in this way is led to the cover 12 side of the cylinder head 10 through a passage provided on one side of the engine, from which the oil component contained in the blow-by gas is separated.

The blowby gas from which the oil component is separated is led to the intake manifold side through the blowby gas hose when the PCV valve 14 operated by the negative pressure according to the operating region of the engine is opened.

The blow-by gas supplied to the nipple 40 side of the intake manifold 30 along the blow-by hose 16 is introduced into the connection passage 41. The blow-by gas introduced into the connection passage 41 is led to the middle portion of the connection passage 41 by the partition 42, and thus the blow-by gas guided to the middle portion of the connection passage 41 is connected to the connection passage 41. Spreads to both sides.

In this process, the blow-by gas is introduced into the second runner 32 and the third runner 33 through the through holes 36 and 37 formed in the second runner 32 and the third runner 33. do. Subsequently, the first runner 31 and the fourth runner 34 are inputted through the through holes 35 and 38 formed in the first runner 31 and the fourth runner 34. The blow-by gas input to each of the runners 31, 32, 33, and 34 is introduced into the combustion chamber while being mixed with the fresh air and reburned.

In particular, the through hole 35 formed in the middle of the first runner 31 and the fourth runner 34 rather than the through holes 36 and 37 formed in the middle of the second runner 32 and the third runner 33. Since the size of 38 is large, there is no significant difference in the amount of blow-by gas flowing into each runner 31, 32, 33, 34.

Therefore, there is no significant difference in the distribution characteristics of the blow-by gas distributed to each combustion chamber of the engine, thereby improving the combustion characteristics between each combustion chamber.

According to the present invention configured as described above, there is no great difference in the amount of blow-by gas flowing into each combustion chamber through the runner of the intake manifold, so that combustion characteristics between the cylinders are improved, and the engine fuel efficiency is improved and the exhaust gas is improved. In addition to reducing the occurrence of, there is a great advantage that the vibration of the engine is reduced in accordance with the combustion characteristics of the combustion chamber.

Claims (3)

A blow-by gas is formed at the lower side of the runners formed in the intake manifold so that the blow-by gas is distributed to each combustion chamber and flows therein, and through-holes are formed at the intersections of the runners and the connect-pass passages. In the distribution device of, The nipple 40 so that the blow-by gas flowing into the connection passage 41 first flows into the runners 32 and 33 positioned on the intermediate side and then into runners 31 and 34 located on both sides. The partition wall 42 is further formed to a predetermined position of the connection passage 41, the blow-by gas introduced through the nipple 44 is guided to a predetermined position of the connection passage 41, and then the connection passage A blow-by gas distribution device, characterized in that it is configured to spread to both sides of (41) so as to flow into each runner (31, 32, 33, 34). The method of claim 1, The partition wall (42) is a blow-by gas distribution device, characterized in that formed to the intermediate position of the connecting passage (41). The method of claim 1, The diameters of the through holes 36 and 37 located in the middle runners 32 and 33 are 2.5 mm, and the diameters of the through holes 35 and 38 located in the runners 31 and 34 on both sides are Distributor of blow-by gas, characterized in that formed in 3mm.