RU2056515C1 - Internal combustion engine - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: engine has cylinder liner 1 with working surface 2 and piston 3 mounted in sleeve. Piston has crown and lateral surface including flame belt 10, area of grooves 11, 12 and 13 for piston rings and guide belt 14. Appplied to flame belt 10 and guide belt 14 of piston is antifriction coating in form of sections 15 and 16 between which section 17 is located. Section 17 is section of piston lateral surface with no coating. Height h₁ of section 15 of coating on flame belt from piston crown is 0.3 to 0.4 of height of this belt and height h₂ of section 16 of coating on guide belt 14 from its lower edge is 0.2 to 0.4 of height of this belt. Antifriction coating 19 may be applied on working surface 2 of liner 1. Sections of coatings on flame and guide belts of piston which are located at maximum distance over its lateral surface provide fro accurate basing and high stability of piston during its motion in cylinder along working surface of liner, as well as for elimination of cocking, knocking and excessive wear. Besides that, temperature and thermal stress of piston and sleeve are equalized in height. EFFECT: enhanced efficiency. 3 cl, 3 dwg

Description

 The invention relates to engine building, and in particular to parts of engines with a surface coating.

 A known internal combustion engine comprising a cylinder with a sleeve, a combustion chamber and a piston with a surface coating on its side surface, mounted in the sleeve and having a bottom, a fire belt, grooves for installing the piston rings and a guide belt. A surface coating of heat-resistant material is applied to the flame belt of the piston (German patent N 3304320, class F 02 D 3/10, publ. 1984).

 The known engine due to poor basing of the piston during its movement along the working surface of the liner and distortions in the area of its contact with it has increased wear of parts of the cylinder-piston group and insufficient resource and reliability.

 A known internal combustion engine comprising a cylinder with a sleeve, a combustion chamber and a piston with an anti-friction coating on its side surface, mounted in the sleeve and having a bottom, a fire belt, grooves for installing piston rings and a guide belt. Said nickel coating is applied to the entire height of the piston guide belt (German application N 3937616, class F 02 F 3/10, publ. 1990).

 Internal combustion engines are known in which the surface of the piston guide belt is coated with a thin layer of tin or lead for better performance. Automotive engines, ed. Hovaha M.S. M. Engineering, 1977, p. 437).

 In well-known engines during their operation there is an unsatisfactory basing of the piston when it moves inside the liner and distortions in the area of its contact with it, as well as uneven temperature distribution along the height of the piston and liner and uneven thermal loads of the engine parts. The consequence of this is its insufficient reliability.

 An internal combustion engine is known, comprising a cylinder with a sleeve, a combustion chamber and a piston installed in the sleeve, having a bottom and a side surface including a flame belt, grooves for installing piston rings and a guide belt, the flame and guide belts of the piston side surface having anti-friction coating sections.

 Since the known engine does not determine the optimal location zones of the coated areas on the heat and guide belts of the piston side surface, this does not use reserves for the most effective use of the mentioned surface for supporting the piston in the liner and leveling the temperature of cylinder-piston parts.

 The objective of the invention is to increase the reliability of the engine due to a more complete elimination of distortions of the piston in the liner and leveling the height of the thermal tension of the details of the cylinder-piston group.

 This is achieved by the fact that in an internal combustion engine containing a cylinder with a sleeve, a combustion chamber and a piston installed in the sleeve having a bottom and a side surface including a flame belt, grooves for installing piston rings and a guide belt, the flame and guide belts of the piston side surface have sections with an anti-friction coating, the height of the coating section on the hot belt from the bottom is 0.3-0.5 of the height of this belt, and the height of the coating area on the guide belt from its lower edge is 0.2-0.4 of the height of this belt.

The antifriction coating is applied to the working surface of the sleeve. As the material for said coating, a crystalline porous composite material was used, consisting of solid inclusions of the α-Al ₂ O ₃ phase distributed in a matrix of γ-Al ₂ O ₃ and mullite compounds 3 Al ₂ O ₃ · 2SiO ₂ .

 With this embodiment of the engine, a more accurate basing of the piston lateral surface during its movement along the liner working surface and more efficient use of the reference length of this surface are ensured, skewed parts are eliminated and friction and wear of cylinder piston parts are reduced, automatic control of the heat transfer from hot gases from the combustion chamber is achieved and heat sink from the piston to the sleeve and are aligned in temperature height of these parts. The consequence of this is to increase the reliability of the internal combustion engine.

 In FIG. 1 is a schematic diagram of a proposed internal combustion engine; in FIG. 2 layer of anti-friction coating applied to the surface of the details of the cylinder-piston group, plan; in FIG. 3 same cut.

The engine comprises a cylinder liner 1 with a working surface 2, a piston 3 mounted in the liner, a cylinder head 4, a combustion chamber 5, inlet 6 and exhaust 7 valves, a connecting rod 8 and a crankshaft (not shown). The piston 3 has a bottom 9 and a side surface including the fringe belt 10, the area of the grooves 11, 12, 13 for installing the piston rings and a guide belt 14. A layer of antifriction coating is applied to the flame 10 and guide 14 of the piston belt in the form of sections 15 and 16 between which there is a portion 17 of the side surface of the piston without coating. The coating section 15 on the fire belt 10 starts from the end of the bottom 9 and its length h ₁ in height is 0.3-0.5 of the height of the fire belt. The length h _{2 of the} portion 16 of the coating deposited in the lower part of the guide belt 14, from its lower edge in the direction of the heat zone is 0.2-0.4 of the height of the guide belt.

 An antifriction coating in the form of a layer 18 is applied to the piston bottom 4, in the form of a layer 19 on the working surface 2 of the cylinder liner and layer 20 on the working surfaces of the groove 11 for the first compression piston ring.

As the material for the mentioned coating layers, a composite dispersion-hardened material of a cellular deep-dimensional crystalline structure consisting of inclusions of the high-strength phase α-Al ₂ O ₃ (35-40%) distributed in a matrix of γ-Al ₂ O ₃ (40-50 %) and mullite compounds 3Al ₂ O ₃ · 2SiO ₂ (up to 100%). The layer thickness is 0.1-0.3 mm. With these phase ratios and the depth of the coating layer and by varying the geometric parameters of its structure, it is possible to provide the best antifriction, heat-shielding and strength properties of the coating.

 For coating engine parts (from aluminum alloys or ferrous metals with a layer of aluminum alloys pre-coated on their surface), it is preferable to use anodic-cathodic microarc oxidation technology.

 The engine operates as follows. The gases formed during combustion in the combustion chamber 5 with high pressure and temperature press on the piston 3 and move it in the cylinder. The translational movement of the piston through the connecting rod is converted into rotational motion of the crankshaft. Sections 15 and 16 of the surface coating on the heat and guide belts of the piston, maximally "spaced" along its lateral surface, with a sufficient length of these sections provide effective supporting surfaces, accurate basing and high stability of the piston when it moves in the cylinder along the working surface of the liner, eliminate it distortions, increased wear of parts of the cylinder-piston group. The maximum effect is achieved with the mentioned values of the length of the zones with the coating and is maintained during the entire period of operation of the engine. In addition to reducing wear, the presence of the aforementioned coated areas in the upper part of the heat and lower parts of the guide belts has a positive effect on the temperature distribution along the piston height, especially reducing the temperature of its heat zone, resulting in equalization of temperatures and thermal stresses of parts of the cylinder-piston group, and reduction of deformations of these details. The application of a coating layer on the piston bottom enhances the noted effect. The leveling of the temperature field, as well as the elimination of distortions of the piston in the sleeve, is further facilitated by applying the said coating to the working surfaces of the groove under the first compression ring.

 The pores present in the selected coating material, enhancing its heat-shielding effect, are at the same time capillaries that contribute to the improvement of the lubrication conditions between the rubbing parts. The use of high antifriction properties of the selected coating material in combination with the local location on the heat and guide belts of its layers forming the supports of the moving piston inside the sleeve, as well as coating the working surface of the sleeve provide the maximum reduction of friction forces, reduced wear and increased mechanical efficiency of the engine.

 Reduced wear and thermal deformation of parts of the cylinder-piston group increase the operational reliability of the internal combustion engine.

Claims (3)

 1. INTERNAL COMBUSTION ENGINE, comprising a cylinder with a sleeve, a combustion chamber and a piston mounted in the sleeve, having a bottom and a side surface including a fire belt, grooves for installing piston rings and a guide belt, the heat and guide belts of the piston side surface having antifriction sections coating, characterized in that the height of the coating area on the hot belt from the bottom is 0.3 - 0.5 of the height of this belt, and the height of the coating area on the guide belt from its lower edge is 0.2 - 0.4 height of this belt.  2. The engine according to claim 1, characterized in that the antifriction coating is applied to the working surface of the liner. 3. The engine according to claims 1 and 2, characterized in that the crystalline composite porous material consisting of solid inclusions of the phase α = Al ₂ O ₃ distributed in the matrix γ = Al ₂ O ₃ and mullite compounds is used as the material for the said coating 3Al ₂ O ₃ • 2 SiO ₂ .

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