KR100535537B1 - Oil separator typed cyclone - Google Patents

Abstract

The present invention provides a cyclone-type oil separator in which a conical inner rotor is additionally formed inside a cyclone-type oil separator to separate large oil components contained in the blow-by gas that is lifted from the crank case to the cylinder head cover side. Regarding,

In order to separate oil components contained in the blow-by gas, a cyclone-shaped body having a larger cross-sectional area than the lower side is formed, and a blow-by gas inlet is formed on one side of the upper part of the body, and a blow is provided on the upper and lower sides of the body. In the cyclone type oil separator in which a bi-gas outlet and an oil outlet are formed,

An inner rotary body having a predetermined width that maintains a predetermined space such that a downward passage is provided between the inner diameter and the outer diameter of the body, the lower end of which is rotated and supported by a bearing inside the lower end of the body;

A gas through hole formed through the lower portion of the inner rotating body so that the blow-by gas introduced through the lower passage flows into the inner rotating body;

An oil drain hole penetrated in the middle of a bearing support portion connecting the body and the internal rotating body so that the separated oil component flows downward through the descending passage and flows downward to the body; Characterized in that comprises a.

Description

Oil separator of cyclone type {Oil separator typed cyclone}

The present invention relates to a cyclone-type oil separator, and more particularly, to a conical shape inside a cyclone-type oil separator in order to separate large oil components contained in a blow-by gas that is raised from the crankcase to the cylinder head cover side. It relates to a cyclone type oil separator further formed with an inner rotor of the.

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

The blow-by gas generated in the crankcase is guided to the cylinder head cover provided on the upper side of the cylinder head, and the blow-by gas guided to the cylinder head cover is guided to the intake machine of the engine and reburned. By the way, such a blow-by gas contains an oil component, and the more oil components in the gas, the greater the oil consumption of the engine, and adversely affect the exhaust durability as well as the engine durability. Therefore, a separator for separating oil is formed in the middle of the cylinder head cover through which the blow-by gas passes.

4 is a view illustrating a conventional cyclone-type separator, wherein the body 11 of the separator 10 is formed in a cyclone shape that is normally narrowed as shown in the drawing, and an upper side of the body 11 is blow-by. A blow-by gas inlet 12 through which gas is introduced is formed. In addition, a blow-by gas outlet 13 and an oil outlet 14 are formed at upper and lower ends of the body 11, respectively. That is, the blow-by gas introduced into the blow-by gas inlet 12 is the oil component having a large particle in the process of rotating in the conical direction inside the body 11 is dropped by its own weight to the oil outlet 14 The blow-by gas discharged through and separated from the oil component is led to the intake side of the engine through the blow-by gas outlet 13.

However, even when the separator for separating oil components included in the blow-by gas is formed in a cyclone type, the blow-by gas input into the body of the separator only rotates in the conical direction, so that the blow-by gas is In the process of being raised again after entering the inside of the oil containing a large particle of the oil component was discharged to the oil outlet there was a problem that the separation of the oil is not made sufficiently.

Therefore, the present invention has been made in order to solve the above problems, the conical shape inside the cyclone-type oil separator to separate the large oil components contained in the blow-by gas rising from the crank case to the cylinder head cover side It is an object of the present invention to provide an oil separator of a cyclone type in which an inner rotor of a further is formed.

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

In order to separate oil components contained in the blow-by gas, a cyclone-shaped body having a larger cross-sectional area than the lower side is formed, and a blow-by gas inlet is formed on one side of the upper part of the body, and a blow is provided on the upper and lower sides of the body. In the cyclone type oil separator in which a bi-gas outlet and an oil outlet are formed,

An inner rotary body having a predetermined width that maintains a predetermined space such that a downward passage is provided between the inner diameter and the outer diameter of the body, the lower end of which is rotated and supported by a bearing inside the lower end of the body;

A gas through hole formed through the lower portion of the inner rotating body so that the blow-by gas introduced through the lower passage flows into the inner rotating body;

An oil drain hole penetrated in the middle of a bearing support portion connecting the body and the internal rotating body so that the separated oil component flows downward through the descending passage and flows downward to the body; Characterized in that comprises a.

Hereinafter, a preferred embodiment according to the configuration and operation of the oil separator according to the present invention will be described in detail with the accompanying drawings.

1 is a cross-sectional configuration diagram of an oil separator formed by the present invention, Figure 2 is a view for explaining the internal rotating body according to the present invention, Figure 3 is an operating state diagram of the oil separator formed by the present invention.

Reference numeral 20 shown in the drawing indicates an oil separator formed by the present invention, and reference numeral 30 indicates an internal rotating body according to the present invention.

The body 21 of the oil separator 20 is formed in a cyclone shape having a cross-sectional area of normal and narrow like the body of the oil separator described in the description of the prior art, and the blow-by gas inlet 22 is formed on one side thereof. It is formed in the shape of a nipple, and a blow-by gas outlet 23 for guiding the blow-by gas after the oil component has been separated is formed in the center of the upper side thereof in a nipple shape.

And the inside of the body 21 is accommodated in the inner rotary body 30 that is supported by the bearing 25 to the lower end of the body 21. The inner rotating body 30 is formed in a cone shape that is normally light and narrow and is formed in a size in which a predetermined gap is maintained with the inner surface of the body 21, so that the inner rotating body 30 is formed of the body 21. When it is accommodated therein is provided a down passage 40 that can blow down the blow-by gas.

In particular, a plurality of blades 32 protrude in a helical direction on the outer circumferential surface of the inner rotor 30, which blades 32 receive the pressure of the blow-by gas input to the blow-by gas inlet 22. Received to be formed to transmit the rotational force to the internal rotating body (30). The lower end is rotatably supported by the bearing 25 so that the internal rotating body 30 can be rotated by the rotational force transmitted as described above.

In the middle of the lower side of the inner rotor 30, after the blowby gas introduced through the blowby gas inlet 22 descends along the downcoming passage 40, the oil component having large particles is separated. A gas through hole 34 is formed to penetrate the blow-by gas to the inside of the internal rotating body 30. As shown in the figure, the size of the gas through hole 34 is preferably larger than the lower portion.

In the process of descending the blow-by gas along the down passage 40 provided between the inner circumferential surface of the body 21 and the outer circumferential surface of the inner rotating body 30, the oil component having a large particle contained in the blow-by gas is included in its own weight. By falling downward or hitting the inner surface of the body 21 or the outer circumferential surface of the inner rotor 30 flows in the downward direction, so that the oil component is lowered through the gas through hole 34 to the inner rotor ( In order not to flow into the inside of the 30, the top 36 of the gas through hole 34 is formed in the circumferential direction.

On the other hand, the lower passage 40 is divided into the inner passage 41 and the outer passage 42 by the circumferential partition 28 at the lower position of the feather 36, the inner passage 41 And the outer passage 42 is the main flow direction of the blow-by gas flows along the falling passage 40 leads to the outer passage 42, the flow of blow-by gas flowing to the outer passage 42 is the partition wall It is configured to be able to continue from the lower side of 28 to the upper side of the inner passage 41. And the flow of the blow-by gas leading to the inner passage 41 is guided to the interior of the internal rotating body 30 through the gas through hole 34 and then raised in the body to the upper hole 31 provided on the upper surface thereof. It is configured to be discharged to the blow-by gas outlet 23 through the.

And in the middle of the bearing support portion 24 connecting the lower end of the body 21 and the lower end of the inner rotor 30, the oil drain hole for allowing the separated oil to be discharged to the lower outer side of the body 21 ( 26) is formed.

The operation state of the oil separator composed of the cyclone type as described above is the same.

After the engine is started, the blow-by gas generated inside the crankcase is led to the cylinder head cover side through the blow-by gas line provided in the engine. In this process, the blow-by gas is provided with an oil separator provided in the middle of the blow-by gas line. 20).

The blow-by gas introduced into the blow-by gas inlet 22 of the oil separator 20 transmits a force to the blade 32 provided on the outer circumferential surface of the inner rotating body 30 while passing through the lower passage 40. do. The force applied to the blade 32 is a driving force for rotating the internal rotating body 30, the inner rotating body 30 and the swirl direction of the blow-by gas for the bearing 25 provided at its lower end It will rotate in the same direction.

In this process, some of the large oil components contained in the blow-by gas passing through the falling passage 40 fall down toward the lower passage 40 by its own weight, and some of the body 21 After hitting the inner circumferential surface of the inner circumferential surface and the outer circumferential surface of the inner rotary body 30, it flows down along the wall surface. The oil component flowing down along the inner circumferential surface of the body 21 is lowered to the oil drain hole 26, and the oil component flowing down along the outer circumferential surface of the inner rotor 30 is lower than the inner rotor 30. It is guided to the outer passage 42 by the feather 36 provided on the way, and then flows toward the oil drain hole 26.

In addition, the blow-by gas passing through the descending passage 40 causes the swirl to pass through the outer passage 42 to change the flow direction from the lower side of the partition wall 28 to the inner passage 41. The large oil component falls to the oil drain hole 26 side. The blow-by gas that has passed through the partition wall 28 continues to flow into the inner passage 41, and the flow direction of the blow-by gas is controlled by the feather 36 provided at an upper position of the gas through hole 34. ). In this process, the oil component contained in the blow-by gas collides with the wall surface of the inner passage 41 and falls toward the oil drain hole 26.

The blow-by gas input to the gas through hole 34 is upwardly inside the inner rotor 30 and passes through the upper hole 31 and the blow-by gas outlet 23 of the inner rotor 30 so that the engine intake system Is delivered to.

According to the present invention constituted as described above, the separation function of the oil having a large particle size by receiving the cone-shaped inner rotor inside the oil separator formed of the cyclone type to separate the oil component contained in the blow-by gas This improvement minimizes the consumption of engine oil, and improves the durability of the engine, as well as a huge advantage in terms of exhaust gas emissions.

1 is a cross-sectional view of an oil separator formed by the present invention.

2 is a view for explaining the internal rotating body according to the present invention.

Figure 3 is an operating state of the oil separator formed by the present invention.

Figure 4 is a view for explaining the prior art.

※ Explanation of code for main part of drawing

20: oil separator 21: body

22: blow-by gas inlet 23: blow-by gas outlet

24: bearing support 25: bearing

26 oil drain hole 28 partition wall

30: internal rotor 31: upper hole

32: blade 34: gas through hole

36: feather 40: descending passage

41: inside passage 42: outside passage

Claims (4)

In order to separate oil components contained in the blow-by gas, a cyclone-shaped body having a larger cross-sectional area than the lower side is formed, and a blow-by gas inlet is formed on one side of the upper part of the body, and a blow is provided on the upper and lower sides of the body. In the cyclone type oil separator in which a bi-gas outlet and an oil outlet are formed, The upper and lower narrow shapes in which a predetermined space is maintained between the inner circumferential surface of the body and the outer circumferential surface of the body 21 are provided so that a predetermined space is maintained, and a lower end thereof has a bearing inside the lower end of the body 21. 25) an inner rotary body 30 which is supported by rotation; A gas through hole (34) formed through the lower portion of the inner rotating body (30) so that the blow-by gas introduced through the lower passage (40) flows into the inner rotating body (30); The bearing support part 24 connecting the lower end of the body 21 and the lower end of the internal rotating body 30 so that the separated oil component flows downward through the lower passage 40 and flows downward of the body 21. An oil drain hole 26 formed in the middle of the through hole; Is formed to include more The descending passage (40) is a cyclone-type oil separator, characterized in that the gas passage hole 34 is divided into the inner passage 41 and the outer passage 42 by the partition wall 28. The method of claim 1, A plurality of blades 32 are formed on the outer circumferential surface of the inner rotating body 30 in a spiral direction so that a rotational force is applied to the inner rotating body 30 by receiving the pressure of the blow-by gas downwardly through the lower passage 40. Cyclone type oil separator, characterized in that the protrusion formed. The method of claim 1, On the upper side of the gas through-hole 34 provided on the outer peripheral surface of the lower side of the inner rotating body 30, the oil component separated in the process of blowing down the blow-by gas through the lower passage 40 is the inner rotating body 30 Cyclone-type oil separator, characterized in that the circumferential feather (36) protruded to prevent the flow through the outer peripheral surface of the gas through the hole (34). delete