KR101526605B1 - Oil amount variable oil jet structure depending on pressure of oil - Google Patents

Abstract

The present invention relates to a variable flow regulating piston oil jet structure according to oil pressure. A variable-flow-regulating piston oil-jet structure according to the present invention has two or more branch-type oil passages on a circumferential surface, each of the branch-type oil passages being converged into one oil passage; A sliding tube which is slidably disposed inside the housing and whose one side is closed on at least two oil holes formed on the circumferential surface, the oil holes being in fluid communication with the branch oil passages by sliding; And an elastic member disposed between the closed side of the sliding tube and the other side of the extended line of the closed side. According to the present invention, the variable-flow-regulating piston oil-jet structure according to the present invention allows only a single flow path to flow through the oil jet since the single passage is opened at a low RPM and the flow rate to the oil jet is increased by pushing the sliding pipe inside the main gallery at high RPM In addition, when applied to a high output GDI engine, it is possible to maximize fuel efficiency and piston cooling effect by controlling the flow rate at low RPM and high RPM.

Main Gallery, Cooling Gallery, Oil Pressure, Flow Control, Oil Jet

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable oil pressure regulating piston oil jet structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automobile field, and more particularly, to a piston oil jet structure in which the flow rate is variable according to an oil pressure.

The piston of the internal combustion engine needs to have heat durability at a high temperature as a part that directly contacts and fluctuates at high temperature and high pressure combustion gas during engine operation.

In order to satisfy the heat resistance / durability under such high temperature and high pressure, it is recommended that the temperature of the piston should be controlled to be not more than the proper temperature, and in general, Therefore, the engine oil is injected directly into the piston to ensure the heat-resistance durability of the internal combustion engine piston, thereby ensuring the cooling performance.

For this purpose, the oil spraying part fastened to the cylinder block of the engine is an oil jet. That is, in the oil jet fastened to the cylinder block, the engine oil that has passed through the main gallery pushes the plunger in the check valve into the oil pressure through the inlet port, and from the moment the oil pressure wins the check valve spring force, The oil ejected from the nozzle pipe flows into the cooling gallery of the piston moving between the top dead center and the bottom dead center to cool the piston and is then drained to the oil pan have.

It is an object of the present invention to provide a piston oil jet structure in which the flow rate is variable depending on the oil pressure.

In order to achieve the above and other objects,

A housing having two or more branched oil passages on a circumferential surface thereof, each of the branched oil passages being converged into one oil passage;

A sliding tube which is slidably disposed inside the housing and whose one side is closed on at least two oil holes formed on the circumferential surface, the oil holes being in fluid communication with the branch oil passages by sliding; And

And a resilient member disposed between the closed side of the sliding tube and the other side of the extended line of the closed side, wherein the resilient member is provided with a variable flow rate regulating piston oil jet structure according to the oil pressure.

According to one preferred embodiment of the present invention, one end of the elastic member opposed to the closed side of the sliding tube is fixed to the fixed portion on the side of the cylinder block RR. At this time, it is preferable that the oil hole near the closed side of the sliding tube is larger than the oil hole far from the closed side of the sliding tube.

According to another preferred embodiment of the present invention, it further comprises an ECU logic circuit for sensing the oil pressure, the RPM or both and controlling the amount of movement of the one end of the elastic member facing the closed side of the sliding tube. At this time, it is preferable that the oil hole at a distance from the closed side of the sliding tube is larger than the oil hole near the closed side of the sliding tube.

According to the present invention, the variable-flow-regulating piston oil-jet structure according to the present invention allows only a single flow path to flow through the oil jet since the single passage is opened at a low RPM and the flow rate to the oil jet is increased by pushing the sliding pipe inside the main gallery at high RPM In addition, when applied to a high output GDI engine, it is possible to maximize fuel efficiency and piston cooling effect by controlling the flow rate at low RPM and high RPM.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail with reference to the following illustrative drawings.

1 and 2 show a variable flow regulating piston oil jet structure according to the oil pressure which operates purely according to the oil pressure. Particularly, Fig. 1 shows an internal view when oil pressure is low, and Fig. 2 shows an internal view when oil pressure is high.

Referring to these drawings, a variable flow regulating piston oil jet structure according to the present invention includes a housing 10, a sliding tube 30 which is slidably disposed inside the housing 10, And an elastic member (50) disposed between the closed side of the sliding tube (30) and the other side on the extension line of the closed side.

The housing 10 is provided with two branched oil passages 12a and 12b on the circumferential surface thereof and these branched oil passages 12a and 12b are converged into one oil passage 14 as shown in the figure. .

The sliding tube 30 slidably disposed in the housing 10 has two oil holes (not shown) sized to be in fluid communication with the branched oil passages 12a and 12b by sliding thereof. 32a, 32b are formed. In view of these drawings, the oil hole of the reference numeral 32b should be recognized to be larger than the oil hole of the reference numeral 32a. That is, the oil hole of the reference numeral 32b is a long hole. The structure of the oil hole is designed such that the oil hole leading to the main bearing can be supplied regardless of the position of the sliding pipe.

An elastic member 50 is preferably provided between the closed side of the sliding tube 30, that is, the right side in the figure and the other side on the extension line of the closed side, for example, the cylinder block RR side fixed portion indicated by reference numeral 90 Is a spring in which a constant value is tuned to the oil pressure.

When the pressure of the oil introduced into the sliding tube 30 is low, the oil hole of the reference numeral 32b formed on the sliding tube 30 is formed in the circumferential surface of the housing 10, Only the oil passage is connected and oil is injected.

On the contrary, when the pressure of the oil introduced into the sliding tube 30 is high, the sliding tube 30 is urged to the right side in the figure by the oil pressure as shown in FIG. 2, And pushes the member 50 to the right in the drawing. The oil hole of the reference numeral 32b and the oil hole of the reference numeral 32a formed in the sliding tube 30 are in fluid communication with the oil passage of the reference numeral 12b and the oil passage of the reference numeral 12a formed in the housing 10, And converges to the oil passage 14.

3 and 4 show a variable flow regulating piston oil jet structure according to the oil pressure which is operated by the addition of an ECU logic circuit unlike the structure shown in Figs. Particularly, Fig. 3 shows the inside view when the oil pressure is low, and Fig. 4 shows the inside view when the oil pressure is high.

Referring to these drawings, a variable flow rate control piston oil jet structure according to another aspect of the present invention includes a housing 10, a sliding tube (not shown) slidably disposed inside the housing 10, (30), and an elastic member (50) disposed between the closed side of the sliding tube (30) and the other side on the extension line of the closed side.

The housing 10 is provided with two branched oil passages 12a and 12b on the circumferential surface thereof and these branched oil passages 12a and 12b are converged into one oil passage 14 as shown in the figure. .

The sliding tube 30 slidably disposed in the housing 10 has two oil holes (not shown) sized to be in fluid communication with the branched oil passages 12a and 12b by sliding thereof. 32a, 32b are formed. In view of these drawings, the oil hole of the reference numeral 32a should be recognized to be larger than the oil hole of the reference numeral 32b. That is, the oil hole of the reference numeral 32a is a long hole. The structure of the oil hole is designed such that the oil hole leading to the main bearing can be supplied regardless of the position of the sliding pipe.

The closed side of the sliding tube 30, that is, the right side of the sliding tube 30 in the drawing and the other side on the extension line of the closed side, detects the oil pressure, RPM or both and faces the closed side of the sliding tube And an ECU logic circuit (not shown) for controlling the amount of movement of one end of the elastic member. 3 and 4, the sliding tube 30 is slid under the elastic force of the elastic member 50 whose one movement amount is controlled by the ECU logic circuit, so that the oil holes 32a and 32b, (12a, 12b) communicate with each other. That is, in this embodiment, the elastic member 50 on the right side in the drawing moves the sliding tube 30 on the left side in the drawing, unlike the previous embodiment.

When the pressure of the oil flowing into the sliding tube 30 is low or the RPM is low, the elastic member 50 maintains its original position or is slightly moved by control by the ECU logic circuit, And the branch oil passage of the reference numeral 12a formed on the circumferential surface of the housing 10 is connected to inject the oil.

Conversely, when the pressure of the oil flowing into the sliding tube 30 is high or when the RPM is high, the elastic member 50 is moved to the left in the drawing by the control by the ECU logic circuit as shown in FIG. 4, So that the sliding tube 30 also moves to the left in the drawing. Thus, the oil hole of the reference numeral 32a and the oil hole of the reference numeral 32b formed in the sliding tube 30 are in fluid communication with the oil passage of the reference numeral 12a and the oil passage of the reference numeral 12b formed in the housing 10, And converges to the oil passage 14.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It can be understood that it is possible.

Fig. 1 and Fig. 2 show a variable-flow regulating piston oil-jet structure according to the oil pressure operating in accordance with the oil pressure. Fig. 1 shows an internal view when the oil pressure is low. The inside view when the oil pressure is high is illustrated.

FIGS. 3 and 4 are views showing a variable-flow regulating piston oil-jet structure according to an oil pressure operated by adding an ECU logic circuit, unlike the structures shown in FIGS. 1 and 2. FIG. Fig. 4 shows an internal view when the oil pressure is high. In Fig.

Description of the Related Art

10: housing 12a, 12b ...: branched oil passage

14: (converging type) oil passage 30: sliding tube

32a, 32b ...: Oil hole 50: Elastic member

90: Fixed portion on the side of the cylinder block RR

Claims (5)

A housing having two or more branched oil passages on a circumferential surface thereof, each of the branched oil passages being converged into one oil passage; A sliding tube which is slidably disposed inside the housing and whose one side is closed on at least two oil holes formed on the circumferential surface, the oil holes being in fluid communication with the branch oil passages by sliding; And An elastic member disposed between the closed side of the sliding tube and the other side of the extended line of the closed side, And an ECU logic circuit for sensing oil pressure, RPM or both and controlling the amount of movement of one end of the elastic member facing the closed side of the sliding tube, The sliding tube is slid under the elastic force of the elastic member whose one movement amount is controlled by the ECU logic circuit so that the oil hole communicates with the oil passage, The size of the oil hole communicating with the branch-type oil passage among the oil holes is larger than the size of the remaining oil holes  A variable-flow-rate piston oil-jet structure according to an oil pressure. delete delete delete delete

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