JP2000158119A - Preliminary formed element to be compounded, and compounded light metal member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a compound light metal member of high tensile strength against high cycling fatigue. SOLUTION: A compounded part 32 of a lip part 31 is formed by arranging a preliminary formed element to be compounded containing a metallic fiber material composed of a stainless and the like, in the die, and solidifying it while dupping it in an aluminum alloy molten metal. The metallic fiber material has a fiber diameter of 10-100 μm, preferably 10-70 μm, and is of a long fiber having an aspect ratio of 1,000 or more, and also has volume ratio of 3-35%, preferably 10-25%.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite preform for compounding a metal fiber material or the like with a part of, for example, an engine piston of an automobile, and a composite light metal member such as an engine piston of an automobile.

[0002]

2. Description of the Related Art Aluminum alloys are widely used in automobile engine parts because of their light weight and good thermal conductivity.

For example, Japanese Patent Application Laid-Open No. Sho 60-119348 discloses that a combustion chamber formed on a piston top surface of a piston for a diesel engine is insulated to improve thermal efficiency. Discloses a method for forming a composite of a preform having a porosity of 10 to 40%, which contains a metal fiber such as a nickel alloy having the following. Japanese Patent Application Laid-Open No. 2-176146 discloses a method of forming a fiber reinforced layer by mixing ceramic or carbon fiber material oriented in the piston axial direction and the radial direction into a crown portion of an engine piston. .

[0004]

[0008] However, as shown in FIG.
In the combustion chamber formed on the top surface of the piston for the diesel engine, the explosive force acts as a high cycle fatigue to expand the combustion chamber, so that the tensile stress F1 selectively acts on the piston pin side repeatedly. The combustion chamber is 30
Although it is heated to about 0 ° C., even if the combustion chamber attempts to expand in the radially expanding direction due to the explosion, the surrounding temperature is not so high, so that the expansion is regulated, and conversely a compressive stress F2 acts in a direction perpendicular to the piston pin. The compressive stress F2 repeatedly acts on the portion K1 in the circumferential direction as thermal fatigue due to the compressive stress F2. And tensile strength against high cycle fatigue,
If the elongation is insufficient for each of the thermal fatigue, there is a possibility that a crack may be generated particularly at a portion K1 orthogonal to the piston pin whose movement in the radial direction is restricted by the piston pin.

In order to increase the strength of the combustion chamber against high cycle fatigue and thermal fatigue, a metal fiber material such as stainless steel having a thickness of about 0.2 mm, which is disclosed as an example in the above prior art, is combined. Justification, carbon fiber orientation in the piston axial direction and radial direction, and refining the structure by remelting alone are not enough to increase high cycle fatigue strength and thermal fatigue strength especially at high temperatures. I can't say.

An object of the present invention is to provide a composite preform and a composite light metal member for obtaining a composite light metal member having high tensile strength against high cycle fatigue.

[0007]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems and achieve the object, a composite preform according to the present invention is used for forming a light metal member by pouring a molten metal made of a light metal material into a mold. The preform for compounding containing a metal fiber material compounded at a site where a tensile stress acts on the light metal member, wherein the metal fiber material is 10 to 100 μm
And the fiber orientation direction of the metal fiber material is oriented substantially along the direction of action of the tensile stress.

Preferably, the metal fiber material is 10
It has a fiber diameter of ７０70 μm.

Preferably, the metal fibers are long fibers having an aspect ratio of 1000 or more.

[0010] Preferably, the fiber volume ratio of the metal fiber material is 3 to 35%.

Preferably, the fiber volume ratio of the metal fiber material is 10 to 25%.

Preferably, the metal fibers are stainless steel fibers.

Preferably, the portion of the light metal member to which a tensile stress acts is annular, and the fiber orientation direction of the metal fiber material is oriented in an annular direction.

Preferably, the light metal member is a piston for an engine of an automobile, and the composite preform forms a lip portion of a combustion chamber formed at the top of the piston.

The composite light metal member of the present invention is
A light metal material in a state in which a composite preform containing a metal fiber material having a fiber diameter of 100 μm is oriented such that the fiber orientation direction of the metal fiber material is substantially along the direction of action of tensile stress of the composite light metal member. And then solidified by impregnating and filling the molten metal.

[0016] Preferably, the metal fiber material is 10
It has a fiber diameter of ７０70 μm.

Preferably, the metal fibers are long fibers having an aspect ratio of 1000 or more.

Preferably, the fiber volume ratio of the metal fiber material is 3 to 35%.

Preferably, the fiber volume ratio of the metal fiber material is 10 to 25%.

Preferably, the metal fibers are stainless steel fibers.

Preferably, the portion of the composite light metal member to which a tensile stress acts is annular, and the fiber orientation direction of the metal fiber material is oriented in the annular direction.

Preferably, the composite light metal member is a piston for an automobile engine, and the composite preform forms a lip portion of a combustion chamber formed on the top of the piston.

The composite light metal member according to the present invention has
The composite preform containing a metal fiber material having a fiber diameter of 10 to 25% with a fiber diameter of 70 μm has a fiber orientation direction of the metal fiber material substantially in the direction of the tensile stress acting on the composite light metal member. The composite is formed by impregnating and filling a molten metal made of a light metal material in a state of being oriented along the solidified material.

[0024]

As described above, according to the first and ninth aspects of the present invention, the metal fiber material has a fiber diameter of 10 to 100 μm,
Since the fiber orientation direction of the metal fiber material is oriented substantially along the direction of action of the tensile stress, it is possible to increase the tensile strength against high cycle fatigue using the conventional manufacturing method.

According to the second and tenth aspects of the invention, since the metal fiber material has a fiber diameter of 10 to 70 μm, the tensile strength can be maintained at a higher level.

According to the third and eleventh aspects of the present invention, the tensile strength can be maintained at a higher level because the aspect ratio of the metal fiber is 1000 or more.

According to the fourth and twelfth aspects of the present invention, since the fiber volume ratio of the metal fiber material is 3 to 35%, a tensile strength corresponding to the fiber volume ratio is obtained in consideration of ease of compounding. be able to.

According to the fifth and thirteenth aspects of the present invention, since the fiber volume ratio of the metal fiber material is 10 to 25%, an optimum tensile strength can be obtained in consideration of ease of compounding.

According to the sixth and fourteenth aspects of the present invention, since the metal fibers are stainless steel fibers, the cost of members can be reduced.

According to the seventh and fifteenth aspects, the portion of the light metal member to which the tensile stress acts is annular, and the fiber orientation direction of the metal fiber material is oriented in the annular direction, so that the composite is simply formed. The tensile strength can be increased more efficiently than in the case.

According to the present invention, the light metal member is a piston for an automobile engine, and the composite preform is formed by forming a lip portion of a combustion chamber formed at the top of the piston. By increasing the tensile strength against high cycle fatigue of the part, it is possible to increase the output of the engine.

According to the seventeenth aspect, 10 to 70 μm
The composite preform containing a metal fiber material having a fiber volume ratio of 10 to 25% with a fiber diameter of 10 m is arranged so that the fiber orientation direction of the metal fiber material is substantially the same as the tensile stress acting direction of the composite light metal member. By being impregnated and filled with a melt of light metal material in a state where it is oriented along and solidified, it is possible to maintain a high level of tensile strength against high cycle fatigue using the conventional manufacturing method. In addition, an optimum tensile strength can be obtained in consideration of ease of compounding.

[0033]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. [Composite Light Metal Member] FIG. 1 is a partial sectional view of a composite diesel engine piston according to this embodiment.

As shown in FIG. 1, an aluminum alloy piston 1 (hereinafter abbreviated as piston 1) exemplified as a composite light metal member of the present invention is manufactured by a gas pressure casting apparatus described later, and has an outer periphery of a piston body 2. The portion is formed with a top ring groove 3 for fitting a top ring, a secondary ring groove 4 for fitting a secondary ring, and an oil ring groove 5 for fitting an oil ring. The piston 1 is for a direct injection diesel engine,
An axial center portion is projected from the piston top surface, and a combustion chamber 30 in which a groove of a predetermined shape is formed annularly and uniformly around the axial center.
Are formed. Further, the combustion chamber 30 is formed with an annular lip portion 31 whose opening edge slightly protrudes in the axial direction and defines an entrance to the combustion chamber 30. The piston 1 is formed with a piston pin insertion hole 8 that penetrates the piston body 2 along the diametric direction.

The top ring groove 3 of the piston 1 is integrally compounded with an annular preform for compounding as a compounding portion 6 as described later, and the lip portion 31 of the piston 1 is also compounded as described later. The top ring groove 3 and the lip portion 31 are integrally compounded with the annular preform for compounding as the portion 32.
The other piston body 2 is cast from an aluminum alloy.

The composite portion 6 of the top ring groove 3 is a composite preform formed of a nickel porous body (Celmet manufactured by Sumitomo Electric: volume ratio = about 5%, average pore diameter 0.8 mm). And solidified by impregnating with a molten aluminum alloy.

The composite portion 32 of the lip portion 31 is formed by placing a composite preform containing a metal fiber material made of stainless steel or the like in a mold, impregnating with an aluminum alloy melt, and solidifying. . 10-1 metal fiber material
It has a fiber diameter of 00 μm, preferably 10 to 70 μm, and an aspect ratio (fiber length / fiber diameter) of 1000 or more long fibers, and a volume fraction of 3 to 35%, preferably 10 to 70%.
It has a volume fraction of 25%.

The composite portion 6 of the top ring groove 3 may be composited with a composite preform containing a metal fiber material.

As the metal fiber material, there are tungsten, molybdenum, carbon steel and the like in addition to stainless steel. The stainless fiber material is practical since it has the highest strength and is inexpensive. [Gas Pressure Casting Apparatus] The piston 1 is shown in FIGS.
It is manufactured by the gas pressure casting apparatus shown in FIG. 2 and 3 are schematic cross-sectional views of the gas pressure casting apparatus of the present embodiment in directions orthogonal to each other.

As shown in FIGS. 2 and 3, the gas pressure casting apparatus 10 according to the present embodiment includes outer molds 12L and 12R, which are split molds divided into right and left as a mold 11, and a middle mold disposed below. 13 and an upper die 14 having a feeder portion 14a disposed above, and a product part cavity 15 is formed therein. A portion corresponding to the top ring groove 3 in the mold 11 is a composite preform 7 shown in FIG. 6, and a portion corresponding to the lip portion 31 is a composite preform 3 shown in FIG.
3 are arranged respectively, and a feeder portion 14a formed on the upper mold 14
The pipe 16 is attached to the case where the pressurization by air is performed from the feeder portion 14a. Reference numeral 17 denotes a cast pin for forming a piston pin insertion hole.

The outer molds 12L and 12R can be driven by outer mold cylinders 18L and 18R, the middle mold 13 can be driven by a middle cylinder 19, and the upper mold 14 can be driven by an upper cylinder 20.

In the middle of the pipe 16, there is provided a valve 27 for selectively communicating the feeder section 14a with a pressurized air source and the atmosphere. A cover 2 provided with a cooling mechanism such as a water-cooled copper lump 28
3, the gate 22 is closed, and at the same time, the valve 16 is operated to connect the pipe 16 to the pressurized air source.
From 6, the factory air may be injected to pressurize the molten metal. With this configuration, there is an advantage that the vicinity of the composite portion can be effectively pressurized.

Reference numeral 25 denotes a runner leading from the gate 22 to the product cavity 15, and reference numeral 26 denotes a salt core supported and arranged by a support means (not shown) for forming a cooling oil passage in the piston. .

In the above structure, after pouring a molten metal of an aluminum alloy (for example, JIS standard AC8A) from the sprue 22, the cover 23 is lowered to seal the sprue 22 and at the same time, the pipes 16 to 10 provided in the cover 23 Factory air having a pressure of less than atmospheric pressure (for example, 0.5 to 10 kg / cm2) is injected to pressurize the molten metal for about 50 seconds to 1 minute. At the time of pressurization by air, a part of the molten metal flows into the air vent groove 21 and is cooled and solidified in the air vent groove 21 to seal the air vent groove 21. Then, the molten metal solidified in the air vent groove 21 is removed as burrs as the mold 11 is divided. In addition, the above-mentioned pressurization by air is 10 to 10 minutes after pouring.
It must start within 30 seconds, but this time range
Generally, the time may be set to a time range in which pressure can be effectively applied before solidification of the molten metal. [Detailed Configuration of Upper Die] FIGS. 4 and 5 are sectional views showing the detailed configuration of the upper die 14.

As shown in FIG. 5, a protrusion 14b is formed on the lower end surface of the upper mold 14, and the height of the protrusion 14b is set to the thickness of the preform 33 for compounding. The preform 33 for use can be positioned. However, FIG.
In the configuration described above, since the composite preform 33 is in contact with the protruding portion 14b of the upper die 14, the impregnated aluminum alloy melt is easily cooled and the composite is poor. Therefore, as shown in FIG.
By arranging the preform 33 and the composite preform 33 in the cavity, cooling can be suppressed, and instead of the air vent groove 21, air can be vented from the split surface between the outer die 12 L or 12 R and the upper die 14. it can. [Composite Preform] FIG. 6 is an external view of a composite preform to be compounded in the top ring groove 3. FIG. 7 is an external view of a composite preform to be composited into the lip portion 31, and is a diagram showing an orientation direction of the metal fiber material.

As shown in FIG. 6, the composite preform 7 composited in the top ring groove 3 is a simple annular nickel porous body (Celmet manufactured by Sumitomo Electric: volume ratio = about 5%, average pore diameter 0). .8 mm).

As shown in FIG. 7, the composite preform 33, which is composited to the lip portion 31, compresses the annular metal fiber material aggregate in one direction (the direction of the piston axis) to at least two parts. Give dimensionality. That is, as shown by the arrow in FIG.
Tensile stress F1 selectively acting on the piston pin side during explosion as high cycle fatigue and compressive stress F3 acting in the circumferential direction orthogonal to the piston pin due to explosion as thermal fatigue.
And the like (see FIG. 8), and the fiber orientation direction of the metal fiber material is oriented in the annular direction.

Since the top ring groove 3 and the lip portion 31 are cut by post-processing, it is sufficient that the composite preforms 7 and 33 are merely annular.

The composite preform 33 is made of stainless steel,
Contains a metal fiber material made of tungsten, molybdenum, carbon steel, etc., and has a fiber diameter of 10 to 100 μm, preferably 1
It has a fiber diameter of 0 to 70 μm and an aspect ratio (fiber length /
Fiber diameter) is 1000 or more and has a volume ratio of 3 to 35%, preferably 10 to 25%.

The composite preform 33 may be a composite of a metal fiber material made of stainless steel, tungsten, molybdenum, carbon steel or the like and a ceramic fiber material made of alumina short fiber material or the like. . [Tensile Strength of Composite Light Metal Member] FIG. 9 is a diagram showing the relationship between the fiber diameter of the stainless steel fiber and the high-temperature tensile strength of the composite lip. FIG. 10 is a diagram showing the relationship between the fiber volume ratio of the stainless fiber material and the high-temperature tensile strength of the composite lip. FIG. 11 shows the high-temperature tensile strengths of a cast product made only of an aluminum alloy, a member obtained by compounding two kinds of stainless steel fibers having different fiber diameters, and a member obtained by compounding alumina fiber, based on the fiber volume ratio. FIG. FIG. 12 shows a cast product of only an aluminum alloy, a member in which two types of stainless fibers having different fiber diameters are combined,
It is a figure which shows in comparison based on a fiber volume ratio about each high temperature fatigue strength of the member which compounded the alumina fiber.

As shown in FIG. 9, when a composite preform containing a stainless fiber material having a fiber diameter of 10 to 100 μm and a metal fiber material having a fiber volume ratio of 10% was compounded, The composite member has a tensile strength of about 80 to 130.
MPa, preferably 300 ° C. with a composite preform containing a stainless steel fiber material having a fiber diameter of 10 to 70 μm.
, A high tensile strength of about 110 to 130 MPa can be maintained, and a smaller fiber diameter can improve a high cycle fatigue strength.

Further, as shown in FIG.
When a composite preform containing a stainless fiber material having a fiber volume ratio of 3 to 35% and a fiber preform having a fiber volume ratio of 3 to 35% is composited with a μm stainless fiber material, the composite member has a tensile strength of about 90 at 300 ° C.
２５０250 MPa or more, preferably a tensile strength at 300 ° C. of about 120-230 MPa in a composite preform containing a stainless fiber material having a fiber volume ratio of 10-25%.
Therefore, as the fiber volume ratio increases, the high cycle fatigue strength can be improved.

For example, as shown in FIG.
A composite member obtained by compounding a composite preform containing a stainless fiber material having a fiber volume ratio of 3 to 20% with a fiber volume ratio of 2 to 20% is obtained by subjecting a cast product of only an aluminum alloy to a JIS T6 heat treatment. A composite of fibers,
The tensile strength at 300 ° C is superior to that obtained by compounding a stainless fiber material with a fiber diameter of 150 μm,
It is clear that the higher the fiber volume ratio, the higher the cycle fatigue strength can be improved.

Further, as shown in FIG.
The composite member obtained by compounding a composite preform containing a stainless fiber material having a fiber volume ratio of 3 to 20% in μm is as follows:
Higher temperature of 300 ° C even when compared to a product obtained by subjecting a cast product made of aluminum alloy only to JIS T6 heat treatment, a product obtained by compounding alumina short fiber, or a product obtained by compounding a stainless fiber material with a fiber diameter of 150 μm. Excellent fatigue strength,
The higher the fiber volume ratio, the higher the high temperature fatigue strength. [Heat treatment of composite light metal member] The preforms 7 and 33 for compounding were combined with the top ring groove 3 and the lip portion 31 of the piston body 2 by the gas pressure casting apparatus shown in FIGS. The composite aluminum alloy member is
Heat treatment described below is performed to increase the thermal fatigue strength.

FIG. 13 is a diagram showing a heat treatment procedure for the composite aluminum alloy member. FIG. 14 is a diagram showing heat treatment conditions for a composite aluminum alloy member. FIG. 15 is a diagram showing a comparison between elongation characteristics of an aluminum alloy and a composite aluminum alloy, which change depending on the heat treatment temperature.

As in the prior art, an aluminum alloy member having a composite of a nickel porous body is put into a heating furnace as a JIS standard T6 heat treatment and heated at a temperature of 500 ° C. for 4.5 hours to obtain a nickel porous member. In addition to forming an intermetallic compound layer at the boundary between the body and the aluminum alloy, performing a solution treatment on the aluminum alloy member, performing water quenching, and further performing a tempering treatment at a temperature of 180 ° C. for 5 hours.

Then, the composite aluminum alloy member subjected to the T6 heat treatment is subjected to mechanical cutting to cut the outer peripheral surface of the piston body 2 including the composite portion, as shown in FIG. Top ring groove 3
Are formed, and the secondary ring groove 4 and the oil ring groove 5 are formed.

In contrast to this conventional example, in the present embodiment, FIG.
As shown in FIG. 5, in order to obtain better elongation characteristics than the T6 heat treatment and to increase the thermal fatigue strength of the composited aluminum alloy, for example, the uncomposited aluminum alloy is subjected to the method of FIG. 13 and the heat treatment conditions of FIG. In the alloy portion (or the portion where the alloy ratio is larger than the composite portion) or the composite portion, at least the portion of the lip where the compressive stress F3 acts in the direction orthogonal to the piston pin (the portion requiring thermal fatigue strength). A solution treatment (quenching treatment) is performed at 500 to 510 ° C. for 3 to 6 hours, and an overage treatment is performed at 220 to 300 ° C. for 4 to 12 hours including the stainless fiber material in the portion subjected to the solution treatment. The overaging treatment is a treatment in which the material is tempered at a temperature higher than the T6 heat treatment temperature (180 ° C.), and the material is softened and elongation characteristics can be increased.

By performing the overaging treatment, the elongation characteristics (for example, based on the elongation test of JIS Standard 2241) of the uncomposited alloy portion (or the portion having a larger alloy ratio than the composite portion) and the composite portion are obtained. Both are raised, FIG.
As shown in FIG. 17, the thermal fatigue life is longer than that obtained by the T6 heat treatment, and the high cycle fatigue strength in the high temperature region can be maintained equal to or higher than that obtained by the T6 heat treatment as shown in FIG. 17. .

Further, as shown in FIGS. 18 and 19, of the uncomposited alloy portion (or the portion having a higher alloy ratio than the composite portion) and the composite portion, overaging is required for portions requiring thermal fatigue strength. By performing the remelting treatment (remelting treatment) before and after the treatment, the high cycle fatigue strength is significantly improved at room temperature as compared with the T6 heat-treated member, and even at 300 ° C, the high cycle fatigue strength is substantially the same as that of the T6 heat-treated member. Obtainable.

FIGS. 20 to 22 are views for explaining the purpose of the combination and heat treatment of the present embodiment. FIG. 23 is a sectional view taken along line AA of FIG.

The following is a summary of the heat treatment method of this embodiment. That is, as shown in FIG. 20, at least the piston pin direction of the lip portion 31 of the piston 1 is compounded (or may be compounded annularly), and the metal fiber material is annealed by overaging treatment ( Allows deformation in the direction of the piston pin (softened) and increases high cycle fatigue strength.

As shown in FIG. 21, at least the piston pin direction of the lip portion 31 of the piston 1 is compounded (or may be compounded in a ring shape), and the direction perpendicular to the piston pin is re-melted to obtain an alloy portion. The thermal fatigue strength can be enhanced because the crystal grains of the particles become finer and the elongation characteristics increase.

FIG. 22 At least the piston pin direction of the lip portion 31 of the piston 1 is compounded (may be compounded annularly), the direction orthogonal to the piston pin is re-melted, and further overaged (over-aging). The re-melting treatment may be performed after the aging treatment), since the crystal grains of the alloy part become finer and the elongation characteristics increase, the thermal fatigue strength is increased,
The metal fiber material is annealed to allow deformation in the direction of the piston pin, and high cycle fatigue strength is enhanced.

In the case where the remelting process is partially performed in the above, as shown in FIG. 23, the portion where the remelting portion overlaps with the composite portion 32 is located below the remelted portion. By arranging it obliquely so as to enter, elongation characteristics can be enhanced in a wide range.

The above is the description of the embodiment of the present invention. However, the composite aluminum alloy member manufactured by the present invention is not limited to the piston for a diesel engine as in the above-described embodiment, but includes a bearing cap, a connecting rod, Of course, it can be applied to the manufacture of a cylinder head. Also,
According to the present invention, besides aluminum alloys, other light alloy castings such as magnesium alloys can also be manufactured.

[0067]

[Brief description of the drawings]

FIG. 1 is a partial cross-sectional view of a combined piston for a diesel engine according to the present embodiment.

FIG. 2 is a schematic cross-sectional view of a gas pressure casting apparatus of the present embodiment in a direction orthogonal to each other.

FIG. 3 is a schematic cross-sectional view of a gas pressure casting apparatus of the present embodiment in a direction orthogonal to each other.

FIG. 4 is a cross-sectional view showing a detailed configuration of the upper die 14;

FIG. 5 is a cross-sectional view showing a detailed configuration of the upper die 14;

6 is an external view of a composite preform to be composited with the top ring groove 3. FIG.

FIG. 7 is an external view of a composite preform to be composited with the lip portion 31 and is a diagram showing an orientation direction of a metal fiber material.

FIG. 8 is a diagram illustrating tensile stress F1 and compressive stresses F2 and F3 acting on a combustion chamber of a piston for a diesel engine.

FIG. 9 is a diagram showing a relationship between a fiber diameter of a stainless steel fiber and a high-temperature tensile strength of a composite lip portion.

FIG. 10 is a diagram showing the relationship between the fiber volume ratio of a stainless steel fiber material and the high-temperature tensile strength of a composite lip.

FIG. 11 shows the high-temperature tensile strengths of a cast product made of only an aluminum alloy, a member obtained by compounding two kinds of stainless steel fibers having different fiber diameters, and a member obtained by compounding alumina fiber, based on the fiber volume ratio. FIG.

FIG. 12 shows the high-temperature fatigue strength of a cast product of only an aluminum alloy, a member in which two types of stainless fibers having different fiber diameters are combined, and a member in which alumina fibers are combined, based on the fiber volume ratio. FIG.

FIG. 13 is a view showing a heat treatment procedure of the composite aluminum alloy member.

FIG. 14 is a view showing heat treatment conditions for a composite aluminum alloy member.

FIG. 15 is a diagram showing a comparison between elongation characteristics of an aluminum alloy and a composite aluminum alloy which change depending on a heat treatment temperature.

FIG. 16 is a diagram showing the relationship between the aging temperature and the thermal fatigue life.

FIG. 17 is a diagram showing the relationship between high cycle fatigue strength and heat treatment temperature.

FIG. 18 is a diagram showing a comparison between high cycle fatigue life of a T6 heat-treated member and a remelted member at room temperature.

FIG. 19 is a diagram showing a comparison between high cycle fatigue life of a T6 heat-treated member at 300 ° C. and a remelted member.

FIG. 20 is a view for explaining the concept of compounding and heat treatment of the present embodiment.

FIG. 21 is a diagram for explaining the concept of compounding and heat treatment of the present embodiment.

FIG. 22 is a view for explaining the concept of compounding and heat treatment of the present embodiment.

23 is a sectional view taken along line AA of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Aluminum alloy piston 2 ... Piston main body 3 ... Top ring groove 6, 32 ... Composite part 7, 33 ... Composite preformed body 11 ... Mold 12L, 12R ... Outer mold 12b, 14a ... Feeder part 14 ... Upper die 15 ... Product cavity 16 ... Pipes 21, 24 ... Air vent groove 22 ... Gate 23 ... Cover 30 ... Combustion chamber 31 ... Lip

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Yukihiro Sugimoto 3-1 Shinchi, Fuchu-cho, Aki-gun, Hiroshima Mazda F-term (reference) 3J044 AA01 BA04 BA07 BC01 CA01 CA03 DA09 EA01

Claims (17)

[Claims] 1. A preforming for compounding containing a metal fiber material which is compounded in a portion of a light metal member where a tensile stress acts when a molten metal made of a light metal material is poured into a mold to form a light metal member. In the body, the metal fiber material has a fiber diameter of 10 to 100 μm, and the fiber orientation direction of the metal fiber material is oriented so as to be substantially along the action direction of the tensile stress. Preform. 2. The preform according to claim 1, wherein the metal fiber material has a fiber diameter of 10 to 70 μm. 3. The metal fiber has an aspect ratio of 1000.
The composite preform according to claim 1 or 2, wherein the preform is a long fiber. 4. The fiber volume ratio of the metal fiber material is 3 to 35.
%.
12. The preform for composite according to item 9. 5. The fiber volume ratio of the metal fiber material is 10 to 2
The preform for compounding according to claim 4, wherein the content is 5%. 6. The preform for composite according to claim 1, wherein the metal fiber is a stainless steel fiber. 7. The light metal member according to claim 1, wherein a portion of the light metal member to which a tensile stress acts is annular, and a fiber orientation direction of the metal fiber material is oriented in an annular direction.
The preform for compounding according to any one of the above. 8. The preform according to claim 1, wherein the light metal member is a piston for an automobile engine, and the composite preform forms a lip of a combustion chamber formed at the top of the piston. The preform for compounding according to any one of the preceding claims. 9. A composite preform containing a metal fiber material having a fiber diameter of 10 to 100 μm such that the fiber orientation direction of the metal fiber material is substantially along the action direction of the tensile stress of the composite light metal member. A composite light metal member characterized in that it is composited by impregnating and filling a molten metal made of a light metal material in a state of being oriented and solidifying. 10. The composite light metal member according to claim 9, wherein the metal fiber material has a fiber diameter of 10 to 70 μm. 11. An aspect ratio of the metal fiber is 100.
The filament is a long fiber of 0 or more.
0. The composite light metal member according to 0. 12. The fiber volume ratio of the metal fiber material is 3 to 3.
The composite light metal member according to any one of claims 9 to 11, wherein the composite light metal member is 5%. 13. The fiber volume ratio of the metal fiber material is 10 to 10.
The composite light metal member according to claim 12, wherein the ratio is 25%. 14. The composite light metal member according to claim 9, wherein the metal fiber is a stainless steel fiber. 15. The composite light metal member according to claim 9, wherein a portion of the composite light metal member on which a tensile stress acts is annular, and a fiber orientation direction of the metal fiber material is oriented in an annular direction.
15. The composite light metal member according to any one of claims 14 to 14. 16. The composite light metal member is a piston for an automobile engine, and the composite preform forms a lip of a combustion chamber formed on a top of the piston. The composite light metal member according to any one of the above. 17. A fiber having a fiber diameter of 10 to 70 μm and a diameter of 10 to 25.
% In a state in which the preform for compounding containing a metal fiber material having a fiber volume ratio of 1.5% is oriented such that the fiber orientation direction of the metal fiber material is substantially along the direction of action of the tensile stress of the compound light metal member. A composite light metal member which is composited by impregnating and filling a molten metal made of a material and solidifying the same.