JP2015165104A - cylinder lubrication system and cylinder lubrication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow cylinder oil to adhere to a cylinder liner slide surface more uniformly while suppressing oil consumption.SOLUTION: A cylinder lubrication system comprises a plurality of stages of lubrication holes 8 and 9 provided in a cylinder liner 1 with respect to a slide direction of a piston 3, cylinder oil being injected from the lower-stage lubrication hole 8 toward an inner surface of the cylinder liner 1, and the cylinder oil being lubricated from the upper-stage lubrication hole 9 provided above the lower-stage lubrication hole 8 out of the lubrication holes 8 and 9 to the inner surface of the cylinder liner 1 or a piston ring 2 of the piston 3.

Description

  The present invention relates to a cylinder lubrication system and a cylinder lubrication method.

  In order to lubricate the cylinder liner and piston ring in an internal combustion engine, an oil injection hole is provided on the inner surface of the cylinder liner, and lubricating oil (cylinder oil) is supplied or injected into the cylinder according to the position of the reciprocating piston. ing.

  The oil supply system that supplies cylinder oil is either a mechanical type that drives the oil supply device in mechanical synchronization with the rotation of the internal combustion engine, or an electronic device that controls the opening / closing time of the solenoid valve to adjust the injection timing and amount of cylinder oil. There are control formulas (for example, also called ECL (Electronically Controlled Lubricating System)). Also, the lubrication method is to supply cylinder oil from the lubrication hole and spread the cylinder oil on the cylinder liner sliding surface by the piston ring, or atomize the cylinder oil during the piston ascending stroke, There is a method in which an oil film is distributed on the sliding surface of the cylinder liner in advance by using a method (also called a SIP (Swirl Injection Principle) system). In the following Patent Documents 1 and 2, a technology related to the SIP system is disclosed.

  Patent Documents 3 and 4 disclose a technique in which the oil supply holes are arranged in a plurality of rows with respect to the sliding direction of the piston, and the upper row oil supply timing is set to be later than the lower row oil supply timing. . Cylinder oil is supplied into the cylinders by a method of spreading the cylinder oil on the sliding surface of the cylinder liner by a piston ring instead of the SIP system in each of the oil supply holes in each row.

JP-T-2002-529648 Special table 2012-530866 gazette JP-A 61-279716 Japanese Utility Model Publication No. 6-63806

  When the above-mentioned SIP system is adopted, the scavenging swirl generated in the cylinder is used, so that the distribution of the cylinder oil on the cylinder liner sliding surface is considered to be uniform as compared with the method in which the cylinder oil is expanded by the piston ring. It was done. However, the inventors have found that the cylinder oil is thinly attached and non-uniform at a position away from the oil injection hole on the cylinder liner sliding surface. In particular, in a long stroke diesel engine, according to the conventional SIP system, it was found that cylinder oil could not be properly distributed, and the cylinder liner was worn away from the lubrication hole.

  The present invention has been made in view of such circumstances, and a cylinder lubrication system capable of more uniformly adhering cylinder oil onto a cylinder liner sliding surface while suppressing oil consumption and An object is to provide a cylinder lubrication method.

In order to solve the above problems, the cylinder lubrication system and the cylinder lubrication method of the present invention employ the following means.
In other words, the cylinder lubrication system according to the present invention includes a lubrication hole provided in a plurality of stages with respect to the sliding direction of the piston in the cylinder liner, and the lubricating oil is supplied from the first lubrication hole of the lubrication hole to the cylinder. The lubricating oil is injected into the inner surface of the cylinder liner or the piston ring of the piston from the second oil supply hole of the oil supply hole, which is injected toward the inner surface of the liner and provided above the first oil supply hole. It is characterized by being.

  According to this configuration, the lubricating oil is injected from the first oil supply hole and attached to the inner surface of the cylinder liner by the scavenging swirl. Then, the lubricating oil is supplied from the second oil supply hole to the inner surface of the cylinder liner or the piston ring of the piston. The lubricating oil injected from the first oil filling hole is diffused by the swirl in the circumferential direction and the axial direction of the cylinder liner, and the lubricating oil is injected from the second oil filling hole, so that the cylinder oil from the first oil filling hole Adhesion is complemented.

  In the above invention, the second oil supply hole injects the lubricating oil into a portion where the lubricating oil is not attached to the first oil supply hole.

  According to this configuration, when attention is paid only to the lubricating oil injected from the first oil filling hole, the adhesion state is uneven or the adhesion range is insufficient, but the lubricating oil is applied to the portion where the adhesion state is thin. The second oil hole is provided so that a large amount of oil is injected, and the lubricating oil is injected, so that the lubricating oil uniformly adheres to the inner surface of the cylinder liner in the circumferential direction.

  In the above invention, in the upward stroke of the piston, before the piston passes through the first oil supply hole, the lubricating oil is injected from the first oil supply hole, and the lubricant is injected into the second oil by the piston. The oil is supplied from the second oil supply hole to the inner surface of the cylinder liner or the piston ring before the oil injection hole passes, after the oil passage hole passes, or at the timing of passing.

  According to this configuration, the lubricated oil is pushed upward or downward on the inner surface of the cylinder liner as the piston moves up or down, and the cylinder oil can be adhered to a wide range, and the cylinder liner is worn. It can be made difficult.

  The cylinder lubrication method according to the present invention is a cylinder lubrication method using a cylinder lubrication system including lubrication holes provided in a plurality of stages with respect to a sliding direction of a piston in a cylinder liner, Lubricating oil is injected from one oil supply hole toward the inner surface of the cylinder liner, and is provided above the first oil supply hole. From a second oil supply hole of the oil supply holes, the inner surface of the cylinder liner or the The lubricating oil is injected into a piston ring of the piston.

  ADVANTAGE OF THE INVENTION According to this invention, cylinder oil can be made to adhere more uniformly on a cylinder liner sliding surface, suppressing oil consumption.

It is a schematic longitudinal cross-sectional view which shows the cylinder oil supply system which concerns on one Embodiment of this invention. It is a block diagram which shows the 1st Example of the cylinder oil supply system which concerns on one Embodiment of this invention. It is a block diagram which shows the 2nd Example of the cylinder oil supply system which concerns on one Embodiment of this invention. It is an expanded view which shows the cylinder liner in 1st Example of the cylinder oil supply system which concerns on one Embodiment of this invention. It is a cross-sectional view which shows the cylinder liner in 1st Example of the cylinder oil supply system which concerns on one Embodiment of this invention, and has shown the positional relationship of a lower oil supply hole and an upper oil supply hole. It is an expanded view which shows the cylinder liner in 2nd Example of the cylinder oil supply system which concerns on one Embodiment of this invention. It is a cross-sectional view which shows the cylinder liner in 2nd Example of the cylinder oil supply system which concerns on one Embodiment of this invention, and has shown the positional relationship of a lower oil supply hole and an upper oil supply hole.

A cylinder lubrication system according to an embodiment of the present invention will be described with reference to the drawings.
The cylinder lubrication system is applied to, for example, a marine two-cycle engine, and supplies new lubricating oil (cylinder oil) into the cylinder in each cycle.

  The cylinder liner 1 is provided with oil supply holes 8 and 9 in a plurality of stages with respect to the sliding direction of the piston 3. In the cylinder liner 1, the piston 3 provided with the piston ring 2 reciprocates in the vertical direction. The piston ring 2 slides with respect to the cylinder liner 1. At this time, the piston ring 2 and the cylinder liner 1 are lubricated by the cylinder oil.

  The oil supply holes 8 and 9 are composed of a lower oil supply hole 8 and an upper oil supply hole 9. The number of holes in the lower oil supply hole 8 and the upper oil supply hole 9 is, for example, 8 as shown in FIG. 2 or 4 as shown in FIG. The plurality of upper oil supply holes 8 and the plurality of lower oil supply holes 9 are arranged at equal intervals in the circumferential direction of the cylinder liner 1.

  The oil lubricator 4 is driven in synchronization with the rotation of the internal combustion engine, and supplies cylinder oil to the lower oil supply hole 8 and the upper oil supply hole 9, respectively. As shown in FIGS. 1 and 2, the lower oil supply hole 8 or the upper oil supply hole 9 and the oil supply device 4 are connected by a lower flow path 13 or an upper flow path 14, and the lower flow path 13 and the upper flow path Cylinder oil flows through 14. The lubricator 4 is provided with a plurality of ports 4A, and the lower flow path 13 or the upper flow path 14 is connected to each port 4A. If the total number of ports 4A of the lubricator 4 and the total number of lower oil holes 8 and upper oil holes 9 do not match, for example, there are eight ports 4A and the number of lower oil holes 8 and upper oil holes 9 is the same. In the case of eight, as shown in FIGS. 1 and 2, the lower passage 13 and the upper passage 14 are provided with branch metal fittings 15, and the cylinder oil is provided in the circumferential direction. Distribute to the holes and each lower oiling hole. The cylinder lubrication amount is proportional to the rotational speed of the lubricator 4, that is, the rotational speed of the engine.

  The oil supply by the upper oil supply hole 9 is, for example, a pressure accumulation type, and as shown in FIG. 1, a check valve 16 and an oil storage device 10 are provided in the upper flow path 9. The oil accumulator 10 includes a cylinder 10a, a piston 10b, and a spring 10c. The elastic force of the spring 10c is such that the pressure in the pressure accumulating chamber 10d inside the oil accumulator 10 is higher than the pressure in the space 11 below the piston 3. 4 is set to be lower than the oil feeding pressure from 4.

  Lubricating by the lower oil filling hole 8 is a SIP (Swirl Injection Principle) system, in which cylinder oil is sprayed during the ascending stroke of the piston 3, and an oil film is previously formed on the sliding surface of the cylinder liner 1 using a scavenging swirl. Distribute. The lower oil supply hole 8 has a nozzle structure at the opening.

  When the piston 3 is in the upward stroke, cylinder oil is sent from the lubricator 4 to the upper and lower lubrication holes 9 and 8 at the same timing. At this time, with respect to the oil supply from the lower oil supply hole 8, the cylinder oil is directly injected from the lower oil supply hole 8 to the inner surface of the cylinder liner 1 at a timing before the piston ring 2 reaches the lower oil supply hole 8. The injected cylinder oil rides on the scavenging swirl and spirally flows in the cylinder liner 1 and adheres to the inner surface of the cylinder liner 1.

  On the other hand, regarding the oil supply from the upper oil supply hole 9, the air in the space 12 above the piston 3 is strongly compressed in the upward stroke of the piston 3, and therefore the pressure thereof is higher than the oil supply pressure of the cylinder oil from the oil injector 4. Therefore, the cylinder oil is sent to the oil storage chamber 10d having a pressure lower than the oil injection pressure, and is temporarily stored in the oil storage chamber 10d.

  After the piston 3 is further raised and the piston ring 2 passes through the upper oil supply hole 9, the pressure in the cylinder liner 1 near the upper oil supply hole 9 becomes substantially equal to the low pressure in the space 11 below the piston 3. As a result, the cylinder oil flows from the upper oil filling hole 9 toward the inner surface of the cylinder liner 1 by the pressure inside the oil storage chamber 10d. At this time, since the pressure in the oil storage chamber 10d is lower than the oil supply pressure of the oil supply device 4, the oil supply from the upper oil supply hole 9 is performed at a moderate speed. When the piston 3 moves down and the piston ring 2 passes through the upper oil supply hole 9, a high pressure of combustion gas acts on the upper oil supply hole 9. Therefore, the lubrication from the oil storage chamber 10d is temporarily interrupted. When the piston 3 is further lowered and the pressure of the combustion gas is lowered, the cylinder oil remaining in the oil storage chamber 10d is again injected into the inner surface of the cylinder liner 1 from the upper oil supply hole 9. The lubricated cylinder oil is pushed upward or downward on the inner surface of the cylinder liner 1 as the piston 3 moves up or down.

  As described above, according to the present embodiment, the oil supply timing from the upper oil supply hole 9 is later than the oil supply timing from the lower oil supply hole 8. That is, the cylinder oil is first injected from the lower oil supply hole 8 and attached to the inner surface of the cylinder liner 1 by the scavenging swirl before the piston 3 passes through the lower oil supply hole 8 in the upward stroke of the piston 3. The cylinder oil is injected from the upper oil supply hole 9 to the inner surface of the cylinder liner 1 after the piston ring 2 passes through the upper oil supply hole 9.

  The cylinder oil injected from the lower oil supply hole 8 is diffused in the circumferential direction and the axial direction of the cylinder liner 1 by swirl. As a result, the cylinder oil injected from one lower oil supply hole 8 adheres to the inner surface of the cylinder liner 1 obliquely upward (see FIGS. 4 and 6). Therefore, the cylinder oil injected from the lower oil supply hole 8 becomes thinner as it goes upward, and unevenness is likely to occur in the circumferential direction. Further, in an engine having a large bore stroke ratio, the cylinder oil injected from the lower oil supply hole 8 adheres to the stroke in the axial direction of the cylinder liner 1.

  If attention is paid only to the cylinder oil injected from the lower oil supply hole 8, the adhesion state is uneven or the adhesion range is insufficient, but according to the present embodiment, the cylinder oil is introduced from the upper oil supply hole 9. By being lubricated, adhesion of the cylinder oil from the lower-stage lubrication hole 8 is complemented. For example, in the positional relationship as shown in FIGS. 4 to 7, the upper oil supply hole 9 is provided in a portion where the cylinder oil adherence state by the lower oil supply hole 8 is thin so that much cylinder oil is injected. Thereby, cylinder oil adheres uniformly to the inner surface of the cylinder liner 1 in the circumferential direction.

  Further, since cylinder oil is injected from both the lower oil supply hole 8 and the upper oil supply hole 9, the cylinder oil adheres to a necessary range of the inner surface of the cylinder liner 1. In particular, in a long stroke engine, cylinder oil can be adhered to a wide range, and therefore, the cylinder liner 1 can be made hard to wear.

  The distance from the TOP ring position (stroke ratio, that is, the ratio of the distance between the TOP ring position and the lubrication hole position and the stroke) is 15% or less for the upper lubrication hole 9 and 15 to 40% for the lower lubrication hole 8 There is. The TOP ring position refers to the position of the upper surface of the uppermost cylinder ring at the top dead center timing.

  In addition, although the said embodiment demonstrated the case where the pressure accumulation type | formula using the lubricator 4 was applied as a method of lubrication of the cylinder oil from the upper stage lubrication hole 9, this invention is not limited to this example. For example, an electronically controlled type (ECL: Electronically Controlled Lubricating System) that lubricates the accumulated cylinder oil while controlling the opening / closing time using a solenoid valve may be applied. The cylinder oil may be injected from the upper oil supply hole 9 to the piston ring 2 at the timing when the piston passes through the upper oil supply hole 9. Furthermore, in the case of timing lubrication, the cylinder oil may be lubricated from the upper oil lubrication hole 9 to the inner surface of the cylinder liner 1 before the piston passes through the upper oil lubrication hole 9.

1 Cylinder liner 2 Piston ring 3 Piston 4 Lubricator 8 Lower oil hole 9 Upper oil hole 10 Oil reservoir

Claims (4)

  The cylinder liner includes oil supply holes provided in a plurality of stages with respect to the sliding direction of the piston, and the lubricating oil is injected from the first oil supply hole of the oil supply holes toward the inner surface of the cylinder liner, A cylinder lubrication system, wherein the lubricating oil is lubricated to an inner surface of the cylinder liner or a piston ring of the piston from a second lubrication hole of the lubrication holes provided above one lubrication hole.   2. The cylinder lubrication system according to claim 1, wherein the second lubrication hole is configured to lubricate the lubricating oil into a portion where the adhesion state of the lubricating oil by the first lubrication hole is thin. In the ascending stroke of the piston, before the piston passes through the first oil supply hole, the lubricating oil is injected from the first oil supply hole,
The lubricating oil is lubricated from the second lubrication hole to the inner surface of the cylinder liner or the piston ring before, after, or when the piston passes through the second lubrication hole. 2. The cylinder lubrication system according to 2. In the cylinder liner, a cylinder lubrication method using a cylinder lubrication system having lubrication holes provided in a plurality of stages with respect to the sliding direction of the piston,
From the first oil supply hole of the oil supply hole, the lubricating oil is injected toward the inner surface of the cylinder liner, and provided above the first oil supply hole, from the second oil supply hole of the oil supply hole, A cylinder lubricating method, wherein the lubricating oil is injected into an inner surface of the cylinder liner or a piston ring of the piston.

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