RU2451810C1 - Ice sleeve assembly - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: engine sleeve assembly comprises piston with compression and scraper rings in contact with cylinder sleeve working surface and grooves filled with nonferrous metal. Three lines of annular grooves are made on cylinder sleeve working surface. Medium line is turned through 90° relative to top and bottom lines. Distance from start of first groove to sleeve top edge equals 10±0.5 mm. Said grooves represent opposed closed isolated grooves with angle of elevation of 17 degrees to sleeve diametral plane and with spacing of 13 mm. Groove cross-section feature hill shape with depth and width equal to 1.5 mm. Maximum distance between adjacent grooves corresponds to distance between top compression ring and bottom scraper ring.

EFFECT: higher quality of operation and wear resistance.

3 dwg

Description

The invention relates to mechanical engineering, mainly for an internal combustion engine (ICE), and can be used in the restoration of cylinder liners.

Closest to the technical nature of the claimed invention relates to a cylinder-piston group of an internal combustion engine [Cylinder-piston group. - Patent RU No. 2186234. Publ. July 27, 2002], including a piston with rings placed on it, which contact the working surface of the sleeve. On the inner surface of the sleeve grooves are made, consisting of two counter helical lines with right and left threads, respectively. The helical lines of the grooves are filled with non-ferrous metal, the angle of their rise lies within 15 ... 60 °, and the step size does not exceed the distance between the upper compression and lower oil scraper rings.

The disadvantages of this device are the reduced wear resistance of the working surface of the cylinder liner and the poor quality of the cylinder-piston group due to the uneven distribution of non-ferrous metal on the working surface of the cylinder liner due to the uneven depth of cut of the screw grooves.

The claimed invention is aimed at eliminating these drawbacks and from its application the following technical result was obtained: improving the quality of work of the cylinder-piston group and the wear resistance of the cylinder liners.

The specified technical result is achieved by the fact that the cylinder liner has three rows of annular grooves. The middle row is rotated 90 ° relative to the upper and lower arrays. The distance from the beginning of the first grooves to the upper end of the sleeve is 10 ± 0.5 mm. The grooves are in the form of oncoming closed rings, separate from each other, with an angle of elevation of 17 degrees to the diametrical plane of the sleeve and a pitch of 13 mm. In the cross section, the grooves are toroidal with a depth and width of 1.5 mm. The maximum distance between adjacent grooves corresponds to the distance between the upper compression and lower oil scraper piston rings.

Figure 1 shows a cylinder liner with altered physical and mechanical characteristics and annular grooves made on its working surface, figure 2 is a cross-sectional view of the groove in section AA, figure 3 is a diagram of the contact of the piston rings with the working surface of the cylinder liner in section BB.

The cylinder-piston group of the internal combustion engine includes a piston 2 with compression 3 and oil scraper 4 rings in contact with the working surface of the cylinder liner 1, and having grooves filled with non-ferrous metal 7. On the working surface of the cylinder liner 1 there are three rows of annular grooves 5 and 6, while the middle row is rotated 90 ° relative to the upper and lower rows, and the distance from the beginning of the first grooves 5 and 6 to the upper end of the sleeve 1 is 10 ± 0.5 mm. Grooves 5 and 6 are made in the form of oncoming closed rings, separate from each other, with an angle of elevation of 17 ° to the diametrical plane of the sleeve 1 and a pitch of 13 mm. In a longitudinal section, the grooves 5 and 6 have a toroidal shape with a depth and width of 1.5 mm. The maximum distance between adjacent grooves 5 and 6 corresponds to the distance between the upper compression 3 and the lower oil scraper 4 piston rings.

The cylinder piston group works as follows.

In the process of internal combustion engine piston 2 with rings 3 and 4 performs a reciprocating movement up and down. In this case, rings 3 and 4, moving along the working surface of the sleeve 1, with plastic deformation remove part of the non-ferrous metal 7 from the grooves 5 and 6 and “smear” it along the working surface of the sleeve 1 from the top dead center to the bottom dead center. This process occurs during all ICE cycles and continues until a non-ferrous metal layer 7 of a certain thickness is formed on the working surface of the sleeve 1. As a result of this process, the coefficient of friction of the working surfaces of the piston rings 3 and 4 and the working surface of the sleeve 1 decreases, and the rings 3 and 4 cease to remove the non-ferrous metal 7 from the grooves 5 and 6. As the thickness of the “smeared” non-ferrous metal 7 decreases from the surface of the sleeve 1 the friction coefficient between the working surfaces of the piston rings 3 and 4 and the working surface of the sleeve 1 increases slightly. At the same time, the intensity of removing the non-ferrous metal 7 from the grooves 5 and 6 by the piston rings 3 and 4 begins to increase, and the process of “smearing” the non-ferrous metal 7 along the working surface of the sleeve 1 is repeated. Thus, the process of applying a layer of non-ferrous metal 7 on the working surface of the sleeve 1 accompanies the entire period of operation of the cylinder-piston ICE group.

Performing an angle of elevation of the grooves of 17 ° to the diametrical plane of the liner filled with non-ferrous metal (copper) will contribute to the formation of a protective film on the liner working surface, as well as reducing the coefficient of friction of the piston rings against the cylinder liner wall.

In addition, the implementation of the grooves in the form of separate closed rings contributes to the accuracy of the depth of their cutting and, accordingly, to increase the uniformity of filling the grooves with non-ferrous metal (copper). Such a design of the working surface of the cylinder liner will improve the quality of the cylinder-piston group and the wear resistance of the cylinder liners.

Claims (1)

Cylinder-piston group of an internal combustion engine, including a piston with compression and oil scraper rings in contact with the working surface of the cylinder liner having grooves filled with non-ferrous metal, characterized in that the cylinder liner has three rows of annular grooves, while the middle row is rotated 90 ° relative to the upper and the lower row, and the distance from the beginning of the first grooves to the upper end of the sleeve is 10 ± 0.5 mm, and the grooves are made in the form of oncoming closed rings, separate from each other, with an angle at Rising 17 ° to the diametrical plane of the liner and in increments of 13 mm, the grooves in the cross section are toroidal with a depth and width of 1.5 mm, the maximum distance between adjacent grooves corresponds to the distance between the upper compression and lower oil scraper piston rings.

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