JP2005069099A - Dimensional stabilization method of cylinder block - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of performing the aging treatment for stabilizing the dimensions of the whole cylinder block uniformly and surely in a short time in simple constitution. <P>SOLUTION: A cylinder liner 11 is inserted in an aluminum alloy 12 to form the cylinder block 1, a heating element 3 is disposed in a journal part 9 of the cylinder block, and a high-frequency induction heating coil 2 is inserted in a bore part 10. In this arrangement, the heating element 3 and the liner 11 are heated by the high-frequency induction heating coil 2 to perform the aging treatment for the cylinder block 1. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method for stabilizing the dimensions of a cylinder block, and more particularly to a method for stabilizing dimensions by aging treatment of a cylinder block formed by casting a cylinder liner with an aluminum alloy.

  Aluminum alloy castings have been used for cylinder blocks of internal combustion engines in recent years. In such an aluminum alloy cylinder block, a cast iron or steel cylinder liner is generally prepared separately in order to ensure desired wear resistance and sliding characteristics in the bore, and this cylinder liner is made of aluminum. It is cast and integrated with an alloy (cast metal).

  In general, cylinder blocks made of an aluminum alloy cause dimensional fluctuations over time because Si and Cu dissolved in a supersaturated state in the aluminum alloy gradually precipitate after casting, resulting in an elongation of about 0.1%. To do. Moreover, since the cylinder block of the internal combustion engine is exposed to combustion heat, the dimensional variation is likely to occur.

The dimensional variation of the cylinder block made of aluminum alloy formed by casting the cylinder liner deteriorates the roundness of the bore during use of the internal combustion engine, and the consumption of oil (lubricating oil) increases. As a countermeasure, a piston ring having a high tension is used to cope with the above-described deterioration of roundness. However, in such a countermeasure, the cylinder liner inner surface and the piston ring constituting the bore inner surface are used. A new problem such as an increase in frictional resistance between the two and a worsening of fuel consumption occurs.
Therefore, it is known to perform an aging treatment after casting the cylinder block in order to stabilize the dimensional variation of the cylinder block in advance. In the conventional aging treatment, for example, T5 treatment is performed in which cast cylinder blocks are placed on a plurality of trays, placed in a furnace, heated to about 200 to 250 ° C., and heated and held for about 2 hours. .

On the other hand, a cylinder liner characterized in that compression residual stress is imparted by applying induction hardening to the inner surface near the opening of a cooling hole formed in a cylinder liner of a diesel engine, thereby greatly improving the fatigue limit. Is known (Patent Document 1).
Also, an induction hardening method in which induction hardening is performed sequentially with a hardening head at a plurality of locations of a workpiece placed during cooling, and the induction heating energy is applied to a later hardening portion corresponding to the earlier of the hardening order. An induction hardening method for reducing the size is known (Patent Document 2).

JP-A-9-184450 Japanese Patent Laid-Open No. 9-3531

  However, in the conventional aging treatment, it is necessary to raise the temperature of not only the entire cylinder block but also the entire furnace, such as a tray that supports the cylinder block, so that it takes time to reach a predetermined temperature. In addition to costs such as costs, there is a problem that a large furnace is required, so that the capital investment becomes large. Moreover, in the conventional aging treatment, the temperature in the furnace was maintained at 200 to 250 ° C. In addition, there is a problem that the aging process takes time because the speed of dimensional variation depends on temperature, that is, is a function of temperature. In addition, there are salt bath heating method and fluidized bed heating method to shorten the heating time, but both methods require washing of salt and fluidized bed medium after heat treatment, which is more costly and capital investment This causes problems such as a large amount.

  Moreover, in the said patent documents 1 and 2, all are what harden | cure by high frequency induction heating, and especially in patent document 2, it is "stabilization of quenching quality and the quenching spots formed. This is intended to reduce dimensional variation, and is completely different from the purpose of stabilizing the dimensions of the cylinder block itself by the aging treatment of the present invention.

  The present invention has been made in view of the above-described problems, and provides a method capable of performing aging treatment for stabilizing the dimensions of the entire cylinder block with a simple configuration in a shorter time. For the purpose.

In order to achieve the above object, the cylinder block dimensional stabilization method according to claim 1 is a method of stabilizing a dimension by aging treatment of a cylinder block formed by casting a cylinder liner with an aluminum alloy. A heating element is disposed in a journal portion of the cylinder block, a high frequency induction heating coil is inserted into a bore of the cylinder block, and the cylinder block is heated by high frequency induction through the heating element and a cylinder liner. To do.
Further, in order to achieve the above object, the invention related to the cylinder block dimensional stabilization method according to claim 2 is a method of stabilizing the dimension by aging treatment of a cylinder block formed by casting a cylinder liner with an aluminum alloy. A first high frequency induction heating coil having a heating element is disposed in a journal portion of the cylinder block, a second high frequency induction heating coil is inserted into the bore of the cylinder block, and the first and second high frequency induction heating are inserted. The cylinder block is high-frequency induction heated by the coil via the heating element and the cylinder liner.

According to the first aspect of the present invention, when a heating element is disposed in a journal portion of a cylinder block in which a cylinder liner is casted with an aluminum alloy and a high frequency induction heating coil is inserted into the bore and energized, it faces the high frequency induction heating coil. The entire cylinder block is heated to a predetermined temperature more uniformly in a short time by high-frequency induction heating through the heating element and the cylinder liner positioned as described above. By maintaining this heated state for a predetermined time, the entire cylinder block is aged more uniformly and the dimensions are stabilized.
According to a second aspect of the present invention, a first high frequency induction heating coil having a heating element is disposed in a journal portion of a cylinder block formed by casting a cylinder liner with an aluminum alloy, and the second high frequency induction heating coil is disposed in the bore of the cylinder block. A high frequency induction heating coil is inserted, and a predetermined current is passed through each high frequency induction heating coil at a predetermined timing for a predetermined time. The journal part of the cylinder block is heated by the first high-frequency induction heating coil generating heat from the heating element, and the bore part is heated by the second high-frequency induction heating coil generating heat from the cylinder liner, so that the entire cylinder block is shortened for a short time. The temperature is raised to a predetermined temperature more uniformly. By maintaining this heated state for a predetermined time, the entire cylinder block is aged more uniformly and the dimensions are stabilized.
In addition, since the speed of dimensional variation depends on the temperature, setting the temperature to be raised by high-frequency induction heating to a temperature higher than that of the prior art (for example, 250 to 400 ° C.) that is put into the furnace, can be shortened. The aging treatment can be performed in (for example, about several seconds to 1 hour).

  According to the present invention, it is possible to achieve the object of providing a method that can easily and reliably perform dimensional stabilization of a cylinder block in a short time with a simple configuration.

The best mode for carrying out the cylinder block stabilization method of the present invention will be described in detail with reference to FIGS. 1 and 2. FIG. In the drawings, the same reference numerals are given to the same or corresponding parts.
The method for stabilizing a cylinder block according to the present invention generally includes forming a cylinder block 1 in which a cylinder liner 11 is cast with an aluminum alloy 12, placing a heating element 3 in a journal portion 9 of the cylinder block, and a bore portion 10. The high frequency induction heating coil 2 is inserted therein, and the heating element 3 and the cylinder liner 11 are heated by the high frequency induction heating coil 2 to age the cylinder block 1.

A cylinder block 1 of an internal combustion engine is formed by casting a cylinder liner 11 made of cast iron, steel, or the like in a portion that becomes each bore portion 10 with an aluminum alloy 12, and the aluminum alloy 12 includes components such as Si and Cu. Is dissolved in supersaturation.
The high frequency induction heating coil 2 has a length corresponding to the length of the cylinder liner 11 casted in the bore portion 10 of the cylinder block 1 and has a diameter having a predetermined distance from the inner surface of the cylinder liner 11. And is connected to a power source capable of supplying a predetermined high-frequency current. The high frequency induction heating coil 2 is supported by an actuator for inserting / retracting the high frequency induction heating coil 2 with respect to the cylinder liner 11 of the bore portion 10.
The heating element 3 is made of cast iron, steel, or the like, similar to the cylinder liner 11. The heating element 3 is arranged in the journal portion of the cylinder block 1 and generates heat by the high frequency induction heating coil 2 inserted into the bore portion 10. The one journal portion 9 is formed into a shape that can be heated. The heating element 3 is supported by an actuator for inserting and retracting the heating element 3 with respect to the journal portion 9. It should be noted that the heating element 3 can be brought into close contact with the journal part 9 or can be positioned so as to be separated from the journal part 9 at a predetermined interval, as required, such as the heating set temperature of the journal part 9.

  In this embodiment, in order to stabilize the dimensions of the cylinder block, the heating element 3 is disposed in the journal portion 9 of the cylinder block 1 and the high frequency induction heating coil 2 is inserted into the bore portion 10 (see FIG. 2). See), the high frequency induction heating coil 2 is energized to perform high frequency induction heating. At this time, the heating element 3 disposed at a predetermined interval at the end of the high frequency induction heating coil 2 and the cylinder liner 11 positioned so as to face the high frequency induction heating coil 2 are heated and the temperature rises. Then, the heat is uniformly conducted and heated in the entire portion constituted by the aluminum alloy 12 of the journal portion 9 and the bore portion 10, and by maintaining this heated state, the aluminum alloy 12 of the entire cylinder block 1 is heated. Si or Cu, which had been dissolved in a supersaturated state, was precipitated to cause permanent elongation, resulting in dimensional fluctuations, and the entire aluminum alloy 12 was subjected to an aging treatment, so that the cylinder block 1 as a whole had a uniform dimension. To stabilize. And the temperature of this aging treatment can be set to a temperature (for example, 250-400 degreeC) higher than the temperature at the time of throwing in in the conventional furnace, and also the cylinder block 1 is raised to this set temperature for a short time. Can be warmed. Furthermore, although the speed of dimensional variation generally depends on the temperature, the set temperature by high frequency induction heating can be increased as described above, so that the time for heating and holding the cylinder block 1, that is, the time required for the aging treatment is shortened (for example, Several seconds to about 1 hour).

Next, the second best mode for carrying out the cylinder block stabilization method of the present invention will be described in detail with reference to FIGS. Note that parts that are the same as or correspond to those in the first embodiment described above are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.
The method for stabilizing a cylinder block according to the present invention generally includes forming a cylinder block 1 in which a cylinder liner 11 is cast with an aluminum alloy 12, and a first high frequency induction having a heating element 3 in a journal portion 9 of the cylinder block 1. The heating coil 4 is arranged, the second high frequency induction heating coil 2 is inserted into the bore portion 9 of the cylinder block 1, and the heating element 3 and the cylinder liner 11 are respectively connected by the first and second high frequency induction heating coils 4, 2. The entire cylinder block 1 is aged by generating heat.

The first high-frequency induction heating coil 4 is formed and arranged so as to be separated from the heating element 3 arranged in the journal part 9 at a predetermined interval. The first high-frequency induction heating coil 4 is integrated with the heating element 3 or separately from the journal part 9. On the other hand, it is supported by an actuator for insertion / retraction.
Since the second high-frequency induction heating coil 2 is the same as the high-frequency induction heating coil 2 in the first embodiment described above, the description thereof is omitted here.

  In this embodiment, in order to stabilize the dimensions of the cylinder block, the heating element 3 is disposed in the journal portion 9 of the cylinder block 1 with the first high-frequency induction heating coil 4 disposed therein, The high frequency induction heating coil 2 is inserted into the bore part 10 (see FIG. 4), and both the high frequency induction heating coils 4 and 2 are energized to perform high frequency induction heating. At this time, the heating element 3 in which the first high-frequency induction heating coil 4 is disposed and the cylinder liner 11 positioned around the second high-frequency induction heating coil 2 are heated to raise the temperature, The entire portion formed by the aluminum alloy 12 of the journal portion 9 and the bore portion 10 is uniformly conducted and heated, and by maintaining this heated state, the aluminum alloy 12 of the entire cylinder block 1 is supersaturated. Si and Cu that were dissolved in the solution precipitate and generate permanent elongation, resulting in dimensional fluctuations, and the entire aluminum alloy 12 is subjected to an aging treatment, so that the overall dimensions of the cylinder block 1 are reliably and uniformly stabilized. To do. Note that the temperature of this aging treatment can be set to a temperature (for example, 250 to 400 ° C.) higher than the temperature at which the conventional aging treatment is performed, and the cylinder block 1 is raised to this set temperature in a short time. As in the first embodiment described above, the temperature of the cylinder block 1 that is heated and held, that is, the time required for the aging treatment can be shortened (for example, about several seconds to 1 hour).

  In the dimensional stabilization method of the cylinder block 1 according to the present invention, in any of the embodiments, the cylinder block 1 is set via the heating element 3 of the journal portion 9 and the cylinder liner 11 of the bore portion 10 by high frequency induction heating. The temperature may be raised to a high temperature, and it may be transferred to a heat retaining means such as a furnace provided next to the high frequency induction heater, so that the elevated temperature is maintained by high frequency induction heating.

The state before the high frequency induction heating coil is inserted into the cylinder liner of the bore part and the heating element is arranged in the journal part for explaining the first embodiment of the cylinder block dimensional stabilization method of the present invention. It is explanatory drawing shown. It is explanatory drawing which shows the state which arrange | positions a high frequency induction heating coil from the state of FIG. 1 in the cylinder liner of a bore part, and arrange | positions a heat generating body to a journal part, and heats it. A second high frequency induction heating coil is inserted into the cylinder liner of the bore for explaining the second embodiment of the cylinder block dimensional stabilization method of the present invention, and the first high frequency induction heating coil is disposed inside. It is explanatory drawing which shows the state before a heat generating body is arrange | positioned at a journal part. FIG. 4 is an explanatory diagram showing a state in which the second high frequency induction heating coil is inserted into the cylinder liner of the bore portion from the state of FIG. 3 and a heating element in which the first high frequency induction heating coil is arranged is arranged in the journal portion and heated. is there.

Explanation of symbols

1: cylinder block, 2: (second) high frequency induction heating coil, 3: heating element, 4: first high frequency induction heating coil, 9: journal portion, 10: bore portion, 11: cylinder liner, 12: aluminum alloy

Claims (2)

A method of stabilizing dimensions by aging a cylinder block formed by casting a cylinder liner with an aluminum alloy,
A heating element is arranged in the journal part of the cylinder block,
Insert a high frequency induction heating coil into the bore of the cylinder block,
A method for stabilizing the dimensions of a cylinder block, characterized by subjecting the cylinder block to high-frequency induction heating via the heating element and a cylinder liner. A method of stabilizing dimensions by aging a cylinder block formed by casting a cylinder liner with an aluminum alloy,
A first high frequency induction heating coil having a heating element is disposed in the journal portion of the cylinder block;
A second high frequency induction heating coil is inserted into the bore of the cylinder block;
A cylinder block dimensional stabilization method, characterized in that the cylinder block is subjected to high-frequency induction heating via the heating element and a cylinder liner by the first and second high-frequency induction superheated cors.

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