JP2014062522A - Engine valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent attachment and accumulation of valve deposit in an engine valve.SOLUTION: An engine valve 1 for sucking air or exhausting air in an internal combustion engine, includes an umbrella portion 10 formed into the umbrella shape, and a shaft portion 20 extended in one side of the umbrella portion 10 and formed into the approximately-rod shape, and a heat transfer coat 30 of high heat conductivity is formed within a prescribed range A of the umbrella portion 10 and the shaft portion 20. An engine valve 1 relating to a second invention, is provided with a top coat 40 of high heat conductivity or high heat insulating performance, covering the heat transfer coat 30.

Description

  The present invention relates to an engine valve in intake or exhaust of an internal combustion engine.

  Many studies and developments have been made for the purpose of improving the thermal efficiency of automobile engines and the like. In the recent automobile industry, gasoline direct injection engines that inject fuel directly into the combustion chamber have been developed.

  A gasoline direct injection engine has many merits such as improved fuel consumption and reduced exhaust gas, but also has a demerit such that deposits are easily generated. This deposit is a soot deposit generated when the fuel burns. When the valve deposit accumulated on the engine valve is peeled off as a large lump by vibration or the like, the combustion chamber is not sealed between the combustion chamber and the valve, and the compression pressure may leak. This can be a cause of poor idling and reduced fuel consumption.

  This valve deposit is formed when the volatile matter of the engine oil that has flowed to the engine valve evaporates due to combustion heat, thereby increasing the viscosity of the engine oil, and soot such as unburned gas adheres to the highly viscous engine oil. Is done.

JP-A-7-310512 JP-A-6-272520 Japanese Patent No. 4252314

  Along with the development of a gasoline direct injection engine, research on techniques for preventing adhesion and accumulation of valve deposits has been conducted. For example, there are Patent Documents 1 to 3.

  Patent Document 1 is a technology related to an engine valve in which a coating layer having an oxidation catalyst function is formed, and a plurality of concave grooves are formed on the outer peripheral surface of the umbrella back portion of the engine valve, and the outer periphery of the umbrella back portion including the concave groove is disclosed. A coating layer having an oxidation catalyst function is formed on the surface.

  According to this, fuel or lubricating oil actively flows into the concave groove, and the amount of fuel etc. attached to the outer peripheral surface of the back of the umbrella other than the concave groove is reduced. Not completely covered by. Therefore, starting from a portion with a small amount of adhesion of fuel or the like, an oxidation catalytic reaction of a high-boiling organic substance or the like occurs, and the high-boiling organic substance is prevented from depositing on the back of the umbrella. That is, by preventing the catalyst surface from being completely covered with high-boiling organic substances or the like, the oxidation catalyst reaction can be promoted and the amount of deposits adhering to the valve can be reduced.

  However, it is difficult to cause an oxidation reaction in the entire range where high-boiling organic substances and the like can be attached and deposited. Therefore, in a part of the engine valve, oxidation reaction does not occur and high boiling point organic substances adhere and deposit, and the deposition range of the high boiling point organic substance further expands from there.

  Patent Document 2 discloses, as an undercoat, an oxide-based film that emits far-infrared light having a wavelength substantially coincident with the far-infrared absorption wavelength of deposits adhering to an intake valve of an engine when heated while using the intake valve. This is an engine intake valve that is coated from the valve stem to the back of the umbrella and coated with a heat-resistant coating on the surface of the base coat as the top coat.

  According to this, the wavelength of far-infrared radiated from the base coat during heating and the far-infrared absorption wavelength of deposits such as engine oil substantially coincide with each other when the engine valve is used, and the self-cleaning function for deposits such as engine oil Is demonstrated. Further, the heat resistance is exhibited by the top coat, and the function of reducing the valve deposit generation is maintained regardless of the temperature rise of the intake valve. In other words, from the valve stem to the back of the umbrella, the self-cleaning function against the deposits such as engine oil and the heat resistance are increased, thereby reducing the generation of valve deposits and maintaining the operating performance of the internal combustion engine and reducing the exhaust gas Can be prevented.

  However, it is difficult to emit far-infrared rays in the entire range where deposits can be deposited and deposited. Therefore, in a part of the engine valve, far infrared rays are not emitted and the self-cleaning function for the attached matter is not exhibited, and the valve deposit adheres and accumulates, and the deposition range of the valve deposit further expands from there.

  Patent Document 3 is a technique for preventing excessive carbon adhesion in components of an internal combustion engine such as an intake valve. In an internal combustion engine that directly injects fuel into a combustion chamber, the intake valve unit reduces the range of the throat of the intake valve. Means for preventing heat carry-out so as to be 380 ° C. or higher, and a notch on the surface that contacts the cylinder head in the valve seat ring disposed in the range of the valve seat of the intake valve of the intake valve unit. .

  According to this, heat radiation can be suppressed by reducing the contact area with the cylinder head in the valve seat ring, and the carbon adhesion can be reduced by setting the intake valve to 380 ° C. or higher.

  However, since the heat insulation around the intake valve is enhanced by the means for preventing heat removal and the heat insulating structure in the valve seat ring, the cooling performance as an internal combustion engine is deteriorated. In addition, since a material having a high thermal conductivity is expensive, the manufacturing cost of the intake valve itself is significantly increased by forming the intake valve with a material having a high thermal conductivity.

  The present invention has been made in view of the above problems, and an object thereof is to prevent adhesion and accumulation of valve deposits in an engine valve.

  An engine valve according to a first invention for solving the above-mentioned problems is an engine valve having an umbrella part formed in an umbrella shape and a shaft part formed in a substantially rod shape extending to one of the umbrella parts, A heat transfer coat having high thermal conductivity is formed in a predetermined range in the umbrella portion and the shaft portion.

  An engine valve according to a second invention for solving the above-described problems is characterized in that the heat transfer coat is covered and a top coat having high thermal conductivity or high heat insulation is formed.

  An engine valve according to a third invention for solving the above-mentioned problems is characterized in that the top coat has a high oil repellency characteristic.

  An engine valve according to a fourth invention for solving the above-described problems is characterized in that a minute uneven shape is formed in the predetermined range.

  An engine valve according to a fifth invention for solving the above-mentioned problems is characterized in that regions having different thermal expansion coefficients or linear expansion coefficients are formed on the surface in the predetermined range.

  An engine valve according to a sixth aspect of the present invention for solving the above-described problems is a region in which the thermal expansion coefficient or the linear expansion coefficient is different, a surface where a part of the heat transfer coat is exposed to the top coat, and a surface of the top coat Or the top coat is made of a different material.

  An engine valve according to a seventh aspect of the present invention for solving the above-described problems is characterized in that a protrusion having an edge shape is formed in the predetermined range.

  An engine valve according to an eighth invention for solving the above-described problems is characterized in that a spiral groove is formed in the predetermined range so as to extend in the axial direction of the shaft portion.

  According to the engine valve according to the first aspect of the present invention, it is easy to transfer the combustion heat in the combustion chamber by forming the heat transfer coat in the predetermined range of the engine valve. it can. Therefore, the engine oil flowing to a predetermined range of the engine valve and the attached valve deposit are heated to a high temperature state, so that the oil content of the engine oil and the valve deposit is burned out and dried, and the valve deposit does not accumulate.

According to the engine valve of the second invention, when a top coat with high heat insulation is formed on the surface of the heat transfer coat formed in a predetermined range of the engine valve, the engine flow is caused by the air flow flowing around the engine valve. Since the predetermined range in the valve is hardly cooled, the heat transfer effect by the heat transfer coating is improved, and the predetermined range of the engine valve can be brought into a higher temperature state. Therefore, the engine oil flowing to the predetermined range of the engine valve and the oil content of the attached valve deposit are more easily burned out, and the valve deposit does not accumulate.
In addition, when a top coat having high thermal conductivity is formed on the surface of the heat transfer coat formed in the predetermined range of the engine valve, the thermal conductivity in the predetermined range of the engine valve is further improved, and the combustion heat in the combustion chamber is increased. Can be transmitted more easily, and the predetermined range of the engine valve can be brought into a higher temperature state. Therefore, the engine oil flowing to the predetermined range of the engine valve and the oil content of the attached valve deposit are more easily burned out, and the valve deposit does not accumulate.

  According to the engine valve of the third invention, the top coat has a high oil repellency characteristic, and adheres to a predetermined range of the engine valve by making it difficult for oil components such as engine oil to adhere to the predetermined range of the engine valve. Since only a small amount of oil is present, the engine oil flowing to a predetermined range of the engine valve and the oil content of the attached valve deposit are more easily burned out, and the valve deposit does not accumulate.

  According to the engine valve according to the fourth aspect of the present invention, the surface of the engine valve in the predetermined range is formed in a minute uneven shape, so that oil droplets such as engine oil that cause valve deposits attached to the predetermined range of the engine valve. An air layer is formed between the engine valve and the surface of the engine valve in a predetermined range, and oil droplets such as engine oil do not adhere to the surface of the engine valve in the predetermined range due to surface tension. In addition, if the surface roughness of the uneven shape is less than or equal to the soot of unburned gas that is the cause of valve deposits, soot of unburned gas etc. will not get caught on the surface in the predetermined range of the engine valve, Adherence of soot such as unburned gas in a predetermined range of the engine valve can be prevented.

  According to the engine valve of the fifth invention, by forming regions having different thermal expansion coefficients or linear expansion coefficients on the surface of the engine valve in a predetermined range, at the boundary between regions having different thermal expansion coefficients or linear expansion coefficients, A difference in expansion occurs. Therefore, stress concentration and cracks occur in the valve deposit attached to the predetermined range of the engine valve, and the attached valve deposit is peeled off from the predetermined range of the engine valve, so that the valve deposit does not accumulate and become large.

  According to the engine valve pertaining to the sixth aspect of the present invention, regions having different thermal expansion coefficients or linear expansion coefficients are formed and transferred between the surface where a part of the heat transfer coat is exposed on the top coat and the surface of the top coat, or Since the top coat is formed of a different material, a complicated manufacturing process and manufacturing method are not required, and the top coat can be easily manufactured.

  According to the engine valve pertaining to the seventh aspect of the present invention, by forming the protrusion on the surface of the engine valve in a predetermined range, stress concentration occurs in the valve deposit attached to the protrusion. Therefore, the valve deposit attached to the predetermined range of the engine valve is cracked, and the attached valve deposit is peeled off from the predetermined range of the engine valve, so that the valve deposit does not accumulate and become large.

  According to the engine valve of the eighth invention, when the engine valve is rotated in one direction when the engine valve slides in the axial direction by forming a concave groove on the surface of the engine valve in a predetermined range, Engine oil that has dripped into the area flows upward along the concave groove. Accordingly, since a small amount of engine oil is in a predetermined range of the engine valve to which soot such as unburned gas can adhere, it becomes easier to burn out by the heat transfer effect of the heat transfer coat. That is, no valve deposit accumulates in a predetermined range of the engine valve.

1 is a longitudinal sectional view showing an engine valve according to Embodiment 1. FIG. 1 is a schematic diagram illustrating an engine valve according to a first embodiment. It is explanatory drawing which shows the surface shape of the engine valve which concerns on Example 1. FIG. It is explanatory drawing which shows the surface shape of the engine valve which concerns on Example 2. FIG. It is explanatory drawing which shows the surface shape of the engine valve which concerns on Example 3. FIG. It is explanatory drawing which shows the surface shape of the engine valve which concerns on Example 4. FIG.

  Embodiments of an engine valve according to the present invention will be described below in detail with reference to the accompanying drawings. Needless to say, the present invention is not limited to the following examples, and various modifications can be made without departing from the spirit of the present invention.

  First, formation and analysis of a valve deposit will be described with reference to FIG.

  A valve deposit that adheres to and accumulates on an engine valve in an internal combustion engine, which is an object of the present invention, includes oil such as engine oil and soot such as unburned gas. Further, the valve deposit adheres and accumulates on the umbrella back surface 11 on the umbrella portion 10 of the engine valve 1 and the shaft portion exposed surface 22 on the umbrella portion 10 side from the step portion 21 called a carbon cutter on the shaft portion 20 of the engine valve 1. Is a predetermined range A (see FIG. 1). Since no soot such as unburned gas is attached to the surface 23 of the shaft portion 20 of the engine valve 1 other than the shaft exposed surface 22 by being gripped by the valve guide 2 or the like, no valve deposit is formed.

  The engine oil dripping from the gap between the shaft portion 20 of the engine valve 1 and the valve guide 2 is heated via the engine valve 1 by the combustion heat in the combustion chamber. The volatile matter of the engine oil on the shaft portion exposed surface 22 and the umbrella back surface 11 of the engine valve 1 is evaporated by the combustion heat, and the viscosity increases. A valve deposit is formed when soot such as unburned gas adheres to high-viscosity engine oil.

  The engine oil that can be used as a valve deposit is a high-viscosity oil whose volatile components have evaporated in a state of about 250 ° C to 350 ° C. The engine oil burns out when it exceeds about 350 ° C. That is, if the shaft portion exposed surface 22 and the umbrella back surface 11 of the engine valve 1 are brought to a state of 350 ° C. or higher, the engine oil is burned out and only soot remains. Therefore, there is no idling failure or fuel consumption reduction as an internal combustion engine.

  The engine valve 1 according to the present invention prevents the adhesion and accumulation of valve deposits by burning the engine oil adhering to the engine valve 1 to about 350 ° C. or higher based on the above analysis results.

  Next, an engine valve 1 according to Embodiment 1 of the present invention will be described with reference to FIGS. 1 to 3.

  The engine valve 1 according to the present embodiment is an intake valve of a gasoline direct injection engine, and is formed in a substantially rod shape extending to one of the umbrella portion 10 and the umbrella portion 10 as shown in FIG. And a shaft portion 20. The predetermined range A in the engine valve 1 is subjected to two types of coating treatment (see FIG. 1): a copper coating 30 of heat transfer coating and a ceramic coating 40 of top coating.

  The copper coating 30 is for the heat of combustion in the combustion chamber to be easily transmitted to the umbrella back surface 11 and the shaft portion exposed surface 22. The predetermined range A in which the copper coating 30 is coated is a range in which the valve deposit can be attached and deposited, and the umbrella back surface 11 on the opposite side to the umbrella surface 12 facing the combustion chamber in the umbrella portion 10 and the shaft portion 20. It is the axial part exposed surface 22 which is a part by the side of the umbrella part 10 rather than the level | step-difference part 21 called a carbon cutter. However, the valve face 13 in the umbrella part 10 is not subjected to film treatment. The valve face 13 in the umbrella portion 10 abuts against a valve seat of a cylinder head (not shown) to keep the combustion chamber airtight. Therefore, since the valve face 13 of the umbrella part 10 needs to be finished with high accuracy, the valve face 13 is excluded from the predetermined range A of the film treatment.

  In the engine valve 1 according to the present embodiment, a copper coating 30 is applied as a heat transfer coat. Since copper has a high thermal conductivity, the combustion heat in the combustion chamber can be transferred to the umbrella back surface 11 and the shaft portion exposed surface 22 with high efficiency. Therefore, the engine oil adhering to the engine valve 1 is heated and burned out at 350 ° C. or higher, so that no valve deposit adheres to and accumulates on the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1.

  Of course, the material of the heat transfer coat is not limited to this example, and any material having a high thermal conductivity may be used. For example, the engine valve 1 may be coated with silver, diamond, platinum or the like. Further, a coolant such as sodium is sealed in the hollow hole of the hollow valve, absorbs the heat of the umbrella surface 12 heated by the combustion heat, and the umbrella back surface 11 and the shaft portion exposed surface 22 of the shaft portion 20 and other surfaces. By releasing to 23, the heat transfer effect can be improved.

  The ceramic coating 40 is for preventing cooling of the engine valve 1 and preventing adhesion of engine oil. The predetermined range A where the ceramic coating 40 is applied is equivalent to the predetermined range A where the copper coating 30 is applied, and the umbrella back surface 11 opposite to the umbrella surface 12 facing the combustion chamber in the umbrella portion 10 and the shaft portion 20. It is a shaft portion exposed surface 22 that is a portion closer to the umbrella portion 10 than the stepped portion 21 called a carbon cutter.

  In the engine valve 1 according to the present embodiment, a ceramic coating 40 is applied as a top coat. Since the ceramic has high heat insulating properties, the copper coating 30 can be prevented from being cooled by being exposed to the intake air. Further, since ceramic is a non-metallic material and has oil repellency, engine oil does not adhere to it.

  Of course, the material of the top coat is not limited to this embodiment. For example, as a top coat for preventing cooling of the engine valve 1 due to intake air, there are coating processes such as nickel and titanium, and as a top coat for preventing adhesion of engine oil, coating processes such as fluorine, boron nitride and DLC are performed. is there.

  In the present embodiment, the engine valve 1 is subjected to the heat transfer coating and the top coating, but the present invention is not limited to this. For example, it is good also as the engine valve 1 which gave only the coating process of the heat transfer coat. Only with the heat transfer coat, the combustion heat in the combustion chamber can be transferred to the umbrella back surface 11 and the shaft portion exposed surface 22 with high efficiency. Therefore, the engine oil adhering to the engine valve 1 is heated and burned out at 350 ° C. or higher, so that no valve deposit adheres to and accumulates on the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1.

  Further, the heat transfer effect of the engine valve 1 can be further strengthened by applying a film having a high thermal conductivity as a top coat on the heat transfer coat. As a top coat for improving the heat transfer effect of the engine valve 1, for example, there is a coating treatment of copper, silver, diamond, platinum or the like.

  Subsequently, in the present embodiment, the surface of the engine valve 1 on which the ceramic coating 40 is applied has a minute uneven shape 50 as shown in FIG. This is to prevent oil droplets 60 such as engine oil from adhering to the surface, and an air layer 70 is formed between the engine valve 1 and the oil droplets 60.

  As the surface roughness of the uneven shape 50, it is preferable that a surface roughness equal to or less than that of the ridges constituting the valve deposit can be secured and the ridges can be prevented from being caught on the surface. Since the particle diameter of the soot is about φ50 to 100 nm, in this embodiment, the surface roughness of the concavo-convex shape 50 is set to 50 nm or less.

  In this embodiment, the concave / convex shape 50 is formed on the ceramic coating 40 by etching the surface after the copper coating 30 and the ceramic coating 40 are applied to the engine valve 1.

  Of course, the formation of the concavo-convex shape 50 is not limited to the present embodiment. For example, the concavo-convex shape 50 may be formed by electrolytic or electroless etching, machining, laser processing, or the like. Further, the concave / convex shape 50 is formed on the copper coating 30 by etching after the copper coating 30 is applied to the engine valve 1, and the ceramic coating 40 is applied on the copper coating 30 on which the fine concave / convex shape 50 is formed. good.

  Next, the operation of the engine valve 1 according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3.

  The combustion heat in the combustion chamber is transmitted to the umbrella portion 10 and the shaft portion 20 of the engine valve 1. Here, the combustion heat from the combustion chamber is efficiently transmitted to the umbrella back surface 11 and the shaft exposed surface 22 by the copper coating 30 having a high thermal conductivity applied to the engine valve 1.

  Further, the copper coating 30 which is a heat transfer portion of the engine valve 1 is covered with the ceramic coating 40 and is not exposed to the air flow flowing through the intake port around the engine valve 1. The highly heat-insulating ceramic coating 40 applied to the engine valve 1 does not absorb the heat of the copper coating 30 that is the heat transfer portion of the engine valve 1 and is not cooled by the airflow flowing through the intake port around the engine valve 1. Therefore, the heat transfer effect by the copper coating 30 can be improved.

  As a result, the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 are efficiently brought into a high temperature state. Oil such as engine oil attached to the umbrella back surface 11 and the shaft exposed surface 22 is heated to 350 ° C. or more and burned out. Therefore, since there is no high-viscosity engine oil that is the cause of the valve deposit, even if soot such as unburned gas adheres to the umbrella back surface 11 and the shaft portion exposed surface 22, no valve deposit is formed.

  Moreover, since the surface of the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 is formed with a minute uneven shape 50, oil such as engine oil hardly adheres. Therefore, since the oil content such as engine oil adhering to the umbrella back surface 11 and the shaft exposed surface 22 is small, it is more easily heated and burned out. That is, since there is no high-viscosity engine oil that causes valve deposits, valve deposits are not formed even if soot such as unburned gas adheres to the umbrella back surface 11 and the shaft portion exposed surface 22.

  Of course, the engine valve 1 according to the present invention is not limited to the intake valve of the gasoline direct injection engine of the present embodiment, but may be adopted as an intake valve or an exhaust valve in other internal combustion engines.

  First, an engine valve 1 according to Embodiment 2 of the present invention will be described with reference to FIG.

  Since the engine valve 1 according to the present embodiment has the same structure as that of the first embodiment except for the material of the top coat, repeated description of the same structure is omitted.

  In the engine valve 1 according to the present embodiment, two types of ceramic coating 40 and nickel coating 41 are applied as a top coat. Since the expansion coefficient is different between ceramic and nickel, regions having different expansion coefficients exist on the surface of the engine valve 1 in the predetermined range A. Therefore, even when the valve deposit adheres, stress concentration and cracks occur in the valve deposit at the boundary between the ceramic coating 40 and the nickel coating 41. That is, the adhered valve deposit is peeled off from the engine valve 1 and therefore does not accumulate and become large.

  Of course, the material of the top coat is not limited to this embodiment, and it is sufficient that the surface of the engine valve 1 in the predetermined range A has regions having different linear expansion coefficients or thermal expansion coefficients. For example, select two or more types of ceramic, nickel, titanium, etc. to prevent engine valve 1 from being cooled by intake air, and fluorine, boron nitride, DLC, etc. May be.

  Moreover, you may give one or more types of film processing as a top coat so that a part of heat transfer coat may be exposed. That is, after coating the heat transfer coat on the engine valve 1, the top coat is coated by masking a part of the heat transfer coat. Alternatively, after the heat transfer coat and the top coat are coated on the engine valve 1, a part of the top coat may be peeled off by etching or processing to expose a part of the heat transfer coat.

  Next, the operation of the engine valve 1 according to the second embodiment of the present invention will be described with reference to FIGS. 1, 2, and 4.

  The combustion heat in the combustion chamber is transmitted to the umbrella portion 10 and the shaft portion 20 of the engine valve 1. Here, the combustion heat from the combustion chamber is efficiently transmitted to the umbrella back surface 11 and the shaft exposed surface 22 by the copper coating 30 having a high thermal conductivity applied to the engine valve 1.

  Further, the copper coating 30 which is a heat transfer portion of the engine valve 1 is covered with the ceramic coating 40 and is not exposed to the air flow flowing through the intake port around the engine valve 1. The highly heat-insulating ceramic coating 40 applied to the engine valve 1 does not absorb the heat of the copper coating 30 that is the heat transfer portion of the engine valve 1 and is not cooled by the airflow flowing through the intake port around the engine valve 1. Therefore, the heat transfer effect by the copper coating 30 can be improved.

  As a result, the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 are efficiently brought into a high temperature state. Oil such as engine oil attached to the umbrella back surface 11 and the shaft exposed surface 22 is heated to 350 ° C. or more and burned out. Therefore, since there is no high-viscosity engine oil that is the cause of the valve deposit, even if soot such as unburned gas adheres to the umbrella back surface 11 and the shaft portion exposed surface 22, no valve deposit is formed.

  Further, since the surface of the engine valve 1 is coated with two kinds of materials, a heat transfer coat and a top coat, peeling of the valve deposit due to a difference in expansion coefficient can be promoted. Therefore, even if the valve deposit adheres, stress concentration and cracks are generated in the valve deposit at the boundary between the ceramic coating 40 and the nickel coating 41, and the adhered valve deposit peels off from the engine valve 1, so that it accumulates and becomes large. There is no.

  By performing one kind of coating treatment as a top coat so that a part of the heat transfer effect is exposed, the coating treatment does not become a complicated operation, so that an increase in the manufacturing cost of the engine valve 1 can be suppressed. Of course, since the heat transfer coat is a film made of a material having a high thermal conductivity, it is preferable that the heat transfer coat be slightly exposed. If the exposed area of the heat transfer coat is small, the reduction of the heat transfer effect can be suppressed.

  Of course, the engine valve 1 according to the present invention is not limited to the intake valve of the gasoline direct injection engine of the present embodiment, but may be adopted as an intake valve or an exhaust valve in other internal combustion engines.

  An engine valve 1 according to Embodiment 3 of the present invention will be described with reference to FIG.

  The engine valve 1 according to the present embodiment has the same structure as that of the first embodiment except for the surface shape in the predetermined range A where the heat transfer coat and the top coat are coated. Omitted.

  In the engine valve 1 according to the present embodiment, a protrusion 80 having an edge-shaped tip is formed in a predetermined range A where the heat transfer coat and the top coat are coated. Even if the valve deposit adheres, stress concentration and cracks occur in the valve deposit at the protrusion 80. Therefore, the adhered valve deposit is peeled off from the engine valve 1 and thus does not accumulate and become large.

  In this embodiment, edge-shaped protrusions are formed on the engine valve 1 by machining, and a copper coating 30 as a heat transfer coat and a ceramic coating 40 as a top coat are uniformly coated on the engine valve 1. A protrusion 80 was formed.

  Of course, the formation of the protrusion 80 is not limited to the present embodiment. For example, the protrusion 80 may be formed by electrolytic or electroless etching, laser processing, or the like. Further, the heat transfer coat having edge-shaped protrusions may be formed on the engine valve 1, and the protrusion 80 may be formed by uniformly coating the top coat on the surface of the heat transfer coat. The protrusions 80 may be formed by uniformly coating the heat coat and forming a top coat having edge-shaped protrusions on the surface of the heat transfer coat.

  Next, the operation of the engine valve 1 according to the third embodiment of the present invention will be described with reference to FIGS. 1, 2, and 5. FIG.

  The combustion heat in the combustion chamber is transmitted to the umbrella portion 10 and the shaft portion 20 of the engine valve 1. Here, the combustion heat from the combustion chamber is efficiently transmitted to the umbrella back surface 11 and the shaft exposed surface 22 by the copper coating 30 having a high thermal conductivity applied to the engine valve 1.

  Further, the copper coating 30 which is a heat transfer portion of the engine valve 1 is covered with the ceramic coating 40 and is not exposed to the air flow flowing through the intake port around the engine valve 1. The highly heat-insulating ceramic coating 40 applied to the engine valve 1 does not absorb the heat of the copper coating 30 that is the heat transfer portion of the engine valve 1 and is not cooled by the airflow flowing through the intake port around the engine valve 1. Therefore, the heat transfer effect by the copper coating 30 can be improved.

  As a result, the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 are efficiently brought into a high temperature state. Oil such as engine oil attached to the umbrella back surface 11 and the shaft exposed surface 22 is heated to 350 ° C. or more and burned out. Therefore, since there is no high-viscosity engine oil that is the cause of the valve deposit, even if soot such as unburned gas adheres to the umbrella back surface 11 and the shaft portion exposed surface 22, no valve deposit is formed.

  In addition, since the edge-shaped protrusion 80 is formed in the predetermined range A where the heat transfer coat and the top coat are coated, peeling of the valve deposit due to stress concentration can be promoted. Therefore, even when the valve deposit adheres, stress concentration and cracks occur in the valve deposit at the protrusion 80. Therefore, the adhered valve deposit is peeled off from the engine valve 1 and thus does not accumulate and become large.

  Of course, the engine valve 1 according to the present invention is not limited to the intake valve of the gasoline direct injection engine of the present embodiment, but may be adopted as an intake valve or an exhaust valve in other internal combustion engines.

  An engine valve 1 according to Embodiment 4 of the present invention will be described with reference to FIG.

  The engine valve 1 according to the present embodiment has the same structure as that of the first embodiment except for the surface shape in the predetermined range A where the heat transfer coat and the top coat are coated. Omitted.

  In the engine valve 1 according to the present embodiment, the concave groove 90 is formed in the predetermined range A where the heat transfer coat and the top coat are coated. In this embodiment, a spiral groove 90 is formed in the shaft portion 20 of the engine valve 1 so as to extend in the axial direction.

  When the engine valve 1 slides in the axial direction, the engine oil dripping onto the umbrella portion 10 and the shaft portion 20 of the engine valve 1 by rotating in one direction is moved upward along the concave groove 90 (engine It flows to the one end side of the valve 1 where the umbrella portion 10 is not formed. Therefore, since there is no engine oil on the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 to which soot such as unburned gas can adhere, a valve deposit is not formed.

  In this embodiment, a spiral recess is formed in the engine valve 1 by machining, and a copper coating 30 as a heat transfer coat and a ceramic coating 40 as a top coat are uniformly coated on the engine valve 1. A concave groove 90 was formed.

  Of course, the formation of the concave groove 90 is not limited to the present embodiment. For example, the groove 90 may be formed by electrolytic or electroless etching, laser processing, or the like. The engine valve 1 may be provided with a heat transfer coat having a spiral recess, and the groove 90 may be formed by uniformly coating the top coat on the surface of the heat transfer coat. The groove 90 may be formed by uniformly coating the heat coat and forming a top coat having a spiral recess on the surface of the heat transfer coat.

  Next, the operation of the engine valve 1 according to the fourth embodiment of the present invention will be described with reference to FIGS. 1, 2, and 6. FIG.

  The combustion heat in the combustion chamber is transmitted to the umbrella portion 10 and the shaft portion 20 of the engine valve 1. Here, the combustion heat from the combustion chamber is efficiently transmitted to the umbrella back surface 11 and the shaft exposed surface 22 by the copper coating 30 having a high thermal conductivity applied to the engine valve 1.

  Further, the copper coating 30 which is a heat transfer portion of the engine valve 1 is covered with the ceramic coating 40 and is not exposed to the air flow flowing through the intake port around the engine valve 1. The highly heat-insulating ceramic coating 40 applied to the engine valve 1 does not absorb the heat of the copper coating 30 that is the heat transfer portion of the engine valve 1 and is not cooled by the airflow flowing through the intake port around the engine valve 1. Therefore, the heat transfer effect by the copper coating 30 can be improved.

  As a result, the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 are efficiently brought into a high temperature state. Oil such as engine oil attached to the umbrella back surface 11 and the shaft exposed surface 22 is heated to 350 ° C. or more and burned out. Therefore, since there is no high-viscosity engine oil that is the cause of the valve deposit, even if soot such as unburned gas adheres to the umbrella back surface 11 and the shaft portion exposed surface 22, no valve deposit is formed.

  Further, since the spiral groove 90 is formed in the shaft portion 20 of the engine valve 1 so as to extend in the axial direction in the predetermined range A where the heat transfer coat and the top coat are coated, the heat transfer coat and the top coat are formed. The engine oil in the predetermined range A where the coat is coated can be removed. Therefore, when the engine valve 1 slides in the axial direction, the engine oil that has dripped onto the umbrella portion 10 and the shaft portion 20 of the engine valve 1 is moved upward along the concave groove 90 by rotating in one direction. It flows to (one end side where the umbrella part 10 in the engine valve 1 is not formed). Therefore, since there is no engine oil on the umbrella back surface 11 and the shaft portion exposed surface 22 of the engine valve 1 to which soot such as unburned gas can adhere, a valve deposit is not formed.

  Of course, the engine valve 1 according to the present invention is not limited to the intake valve of the gasoline direct injection engine of the present embodiment, but may be adopted as an intake valve or an exhaust valve in other internal combustion engines.

DESCRIPTION OF SYMBOLS 1 Engine valve 2 Valve guide 10 Umbrella part 11 Umbrella back surface 12 Umbrella part umbrella surface 13 Umbrella part valve face 20 Shaft part 21 Shaft part step part (carbon cutter part)
22 Shaft portion exposed surface 23 of shaft portion Surface 30 other than shaft portion exposed surface of shaft portion Copper coating 40 Ceramic coating 41 Nickel coating 50 Concavity and convexity 60 Oil droplet 70 Air layer 80 Projection portion 90 Concave groove

Claims (8)

An engine valve having an umbrella portion formed in an umbrella shape and a shaft portion formed in a substantially rod shape extending to one of the umbrella portions,
An engine valve characterized in that a heat transfer coat having high thermal conductivity is formed in a predetermined range in the umbrella part and the shaft part.   The engine valve according to claim 1, wherein the heat transfer coat is covered to form a top coat having high thermal conductivity or high heat insulation.   The engine valve according to claim 2, wherein the top coat has high oil repellency.   The engine valve according to any one of claims 1 to 3, wherein a minute uneven shape is formed in the predetermined range.   The engine valve according to claim 2 or 3, wherein regions having different thermal expansion coefficients or linear expansion coefficients are formed on a surface in the predetermined range. The regions having different thermal expansion coefficients or linear expansion coefficients are formed by a surface where a part of the heat transfer coat is exposed to the top coat and the surface of the top coat, or the top coat is made of a different material. The engine valve according to claim 5, wherein the engine valve is formed.   The engine valve according to any one of claims 1 to 3, wherein a protrusion having an edge shape is formed in the predetermined range.   The engine valve according to any one of claims 1 to 3, wherein a spiral concave groove extending in the axial direction of the shaft portion is formed in the predetermined range.

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