KR100427071B1 - Oil drain apparatus for oil gallery of piston - Google Patents

Abstract

The present invention relates to an oil discharge device of a piston oil gallery having a component for guiding a discharge direction of oil to an inner surface of a piston at an outlet of an oil gallery formed at an intermediate portion of a piston for cooling the piston.

In the annular oil gallery in the middle portion of the piston is formed in the form of weight, the oil outlet and the oil inlet is formed in the lower side of both sides of the oil gallery,

A nozzle is formed below the oil outlet formed in the oil gallery of the piston to direct the discharge direction of the oil toward the inner wall of the piston, wherein the nozzle has a small diameter inside the elbow bent at an angle of 90 degrees. A hole is formed and is screwed to the oil outlet.

Description

Oil drain apparatus for oil gallery of piston

The present invention relates to an oil discharge device of a piston oil gallery, and more particularly, a component for guiding a discharge direction of oil to an inner surface of a piston at an outlet of an oil gallery formed at an intermediate portion of a piston for cooling the piston. The oil discharge device of the installed piston oil gallery.

In general, in the case of a diesel engine, which is a high-temperature, high-pressure compression ignition engine, the combustion temperature is very high, so the temperature of the piston is considerably higher than that of a gasoline engine. Because of this, there is a problem that the occurrence of sintering of the piston ring and the thermal fatigue stress of the piston is increased to damage the engine.

In order to prevent such a phenomenon, an oil gallery for cooling the piston is formed in the piston of the diesel engine as shown in FIGS. 2 and 3. The oil gallery 11 is formed by losing weight in an annular portion of the piston 10, the oil inlet 12 and the oil outlet 13 is formed on both sides. That is, in the process of reciprocating the piston 10 up and down, the oil splashed by the pumping of the oil pump flows into the oil inlet 11 and circulates while cooling the piston 10 and then the oil outlet 13 To be discharged.

In general, the oil gallery 11 is formed by a weight loss method in the casting process of the piston, and salt is used in the casting process to lose weight to form the oil gallery 11. That is, an annular ring is formed from the compressed salt, and two pillars are formed to support the annular ring. The pillar is one after the casting will be the oil inlet 12, the other will be the oil outlet (13).

Particularly, after the casting of the piston is finished, the oil inlet 12 is enlarged by a drill to facilitate the inflow of oil into the oil gallery. In the case of the oil outlet 13, the smaller the diameter of the piston, While advantageous for cooling, the size of the holes formed during the casting process is retained.

However, in the case of the piston formed with the oil gallery as described above, since the oil discharged from the oil outlet is directly dropped into the oil pan, bubbles are generated on the oil surface by the kinetic energy and the potential energy of the oil. As such, bubbles generated on the oil surface are supplied to the valve gap adjusting device by the pumping of the oil pump, thereby affecting the normal linear motion of the engine.

Therefore, the present invention has been made to solve the above problems, and more specifically, to guide the discharge direction of oil to the inner surface of the piston at the outlet of the oil gallery formed in the middle of the piston for cooling the piston It is an object to provide an oil drainage device of a piston oil gallery equipped with parts.

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

In the annular oil gallery in the middle portion of the piston is formed in the form of weight, the oil outlet and the oil inlet is formed in the lower side of both sides of the oil gallery,

A nozzle is formed below the oil outlet formed in the oil gallery of the piston to direct the discharge direction of the oil toward the inner wall of the piston, wherein the nozzle has a small diameter inside the elbow bent at an angle of 90 degrees. A hole is formed and is screwed to the oil outlet.

1 is a cross-sectional view of a piston formed by the present invention.

Figure 2 is a side cross-sectional view of a conventional general piston.

Figure 3 is a plan sectional view of a conventional general piston.

※ Explanation of code for main part of drawing

20: piston 21: oil gallery

22: oil inlet 23: oil outlet

24: inner wall surface 30: nozzle

31 body 32 hole

33: screw part

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

1 is a cross-sectional view of a piston formed by the present invention, with reference numeral 20 designating a piston and 30 designating a nozzle formed by the present invention.

The overall shape and structure of the piston 20 is formed as in the prior art. An oil gallery 21 for cooling is formed in the middle portion of the piston 20. The oil gallery 21 is formed in the same manner as in the prior art. In addition, the oil gallery 21 is formed with an oil inlet 22 and an oil outlet 23.

However, in the case of the piston 20 formed by the present invention, the nozzle 30 for directing the discharge direction of the oil toward the inner wall surface 24 of the piston 20 at the oil outlet 23 of the oil gallery 21 is provided. Are assembled.

The nozzle 30 has a relatively small diameter hole 32 formed inside the body 31 bent at an angle of 90 degrees, and a threaded portion 33 is formed on the upper side of the body 31 bent at 90 degrees. It is screwed to the oil outlet 23.

In particular, the nozzle 30 described above is described as being screwed in the embodiment of the present invention reveals that it may be press-fitted.

Referring to the operation and action of the present invention formed as described above are as follows.

When the engine is running, oil for lubricating the engine sliding part and the friction part is pumped by the oil pump. The oil pumped from the oil pump is scattered around the lower part of the piston and around the cylinder by an oil jet (not shown), at which time a part of the scattered oil flows into the oil inlet 22 of the oil gallery 21. .

As such, the oil introduced into the oil gallery 22 in the process of moving the piston 20 is circulated to the oil gallery 21 and contributes to the cooling of the piston 20. The oil circulated through the oil gallery 21 is discharged to the oil outlet 23, and the oil is discharged toward the inner wall surface 24 of the piston 20 by the nozzle 30 formed at the oil outlet 23. Discharged.

As described above, the oil discharged to the inner wall surface 24 of the piston 20 flows along the wall and then falls into the oil pan, thereby reducing the kinetic energy and potential energy of the oil. Therefore, when the oil falls to the oil surface of the oil pan, the generation of bubbles is reduced, thereby improving the cooling performance and the lubricating performance of the oil.

As described above, a nozzle is formed at the oil outlet formed in the oil gallery of the piston to guide the discharge direction of the oil to the inner wall surface of the piston, so that bubbles are generated in the process of dropping the oil passing through the oil gallery into the oil pan. This reduces the cooling and lubrication performance of the oil.

Claims (1)

In the annular oil gallery in the middle portion of the piston is formed in the form of weight, the oil outlet and the oil inlet is formed in the lower side of both sides of the oil gallery, A nozzle 30 is formed below the oil outlet 23 formed in the oil gallery 21 of the piston 20 to direct the discharge direction of the oil toward the inner wall surface 24 of the piston 10. The nozzle 30 has a small diameter hole 32 formed inside the body 31 bent at an angle of 90 degrees and is screwed to the oil outlet 23. Oil drainage device.