The present invention relates to a piston for an internal combustion engine, which is provided with a plurality of cooling protrusions on a back surface side of a crown portion of the piston, and relates to an improved technique of a production method and a production device for the piston for the internal combustion engine.
As a method of cooling a piston for an internal combustion engine, which is subject to heavy heat load during an engine operating condition, various measures have been taken. As one of the cooling measures, for instance, it is disclosed in the following Patent Document 1.
This piston is formed as an integral member with, for instance, aluminum alloy material, and provided with a plurality of cooling fins that are formed integrally with a back surface side opposite to a crown surface of a crown portion and protrude from the back surface of the crown portion. The cooling fins, which are located on the substantially middle side on the back surface, are formed into a substantially linear shape, while the cooling fins, which are located on an outer circumferential side of the middle side-cooling fins, are formed into an arc shape so as to surround the middle side-cooling fins.
A surface area of the back surface side of the crown portion is increased by the plurality of cooling fins formed integrally with the piston, then a cooling effect during a piston drive is increased.
Patent Document 1: Japanese Unexamined Utility Model Application Publication No. 56-118938 (JP, 56-118938, U)
In the case of the piston disclosed in the Patent Document 1, however, each of the cooling fins is formed so as to protrude downward from the back surface of the crown portion. Therefore, in a case where the piston is cast by a Gravity Die Casting Process (Gravity), when pouring molten metal into a mold (or a die) that has recessed portions for molding the cooling fins, since the molten metal flows into an inside (a bottom side) of the recessed portion from an upper end opening side of the recessed portion, the molten metal hardens with air remaining on the bottom side of the recessed portion.
For this reason, an adequate transcription performance to a molding surface of the mold cannot be ensured, thereby not securing a sufficient surface area of the cooling fin. As a consequence, there is a risk that cooling efficiency of the crown portion will be decreased.
The present invention was made in view of the above technical problem. An object of the present invention is therefore to provide a piston for an internal combustion engine, a piston production device and a piston production method, which are capable of ensuring the adequate transcription performance to the molding surface of the mold while removing the remains of the air on the bottom side of the recessed portion of the mold for molding the protrusions on the crown portion back surface during the casting.
A piston for an internal combustion engine recited in claim 1 comprises: a crown portion having a crown surface that defines a combustion chamber; thrust-side and anti-thrust-side skirt portions formed integrally with the crown portion and sliding on a cylinder wall surface; a pair of apron portions joined to the pair of skirt portions in a circumferential direction, each of the apron portions having a pin boss portion provided with a piston pin hole; a recessed portion formed on a back surface that is an opposite side to the crown surface of the crown portion and extending between the both skirt portions along a substantially longitudinal direction; and a plurality of protrusions formed integrally with a bottom surface of the recessed portion and extending along an arrangement direction of the pair of apron portions or an arrangement direction of the pair of skirt portions. And at least one end edge in a longitudinal direction of each of the protrusions is integrally connected to an inner side surface, which faces the one end edge of the protrusion, of the recessed portion.
As a piston production device, the lower mold is provided with a protruding portion for molding the recessed portion, the protruding portion being formed on an upper surface of a middle portion of an inner surface forming portion that forms each surface of the both skirt portions; and a plurality of groove portions for molding the protrusions, the plurality of groove portions being formed on an upper surface of the protruding portion. And, the lower mold is configured so that a height of the middle portion is set to be higher than those of the other portions of the inner surface forming portion of the lower mold by a height of the protruding portion, and a depth of each of the groove portions is set to be shallower than the height of the protruding portion, a height of an opening formed on at least one end side in a longitudinal direction of each of the groove portions is set to be lower than or the substantially same as a bottom surface of the groove portion, and molten metal poured in the lower mold flows to the bottom surface of each of the groove portions from the opening of the groove portion.
According to the present invention, by making the molten metal flow to the bottom surface side of each of the plurality of groove portions of the lower mold, which mold the plurality of protrusions on the back surface of the crown portion of the piston, during casting, the remains of the air is suppressed, and the adequate transcription performance to the molding surface of the mold can be ensured. It is therefore possible to obtain a desired surface area of the protrusions of the piston.
In the following description, embodiments of a piston for an internal combustion engine, a piston production device and a piston production method according to the present invention will be explained. The piston in the embodiments is applied to a spark ignition gasoline engine.
As shown in
The piston 1 is cast as an integral member with AC8A Al—Si base aluminium alloy as base material, and as shown in
The crown portion 2 has a relatively thick disc shape. The crown portion 2 is provided, on the crown surface 2a defining the combustion chamber 03, with a valve recess (not shown) to prevent interference with an intake valve and an exhaust valve. An outer circumferential portion of the crown surface 2a is shaped into a protruding circumference. The crown portion 2 has, at the outer circumferential portion thereof, three piston ring grooves 2b, 2c and 2d in which pressure rings and/or oil rings 5a to 5c are fitted.
Further, as shown in
As shown in
As shown in
As shown in
Each of the protrusions 7 in the two groups is formed into a linear shape along the axis line Y of the pin boss portions 4b and 4b. That is, the protrusions 7 are formed along an opposing direction of the pair of apron portions 4a and 4a, and arranged parallel to each other with a predetermined width clearance S1 provided between them. Further, both end portions 7a and 7b of the protrusion 7 are joined or connected to the opposing inner side surfaces 6b and 6b at the long side of the recessed portion 6, and an outer surface 7c of the protrusion 7 is formed into a substantially arc shape in cross section. As shown in
As explained above, since the recessed portion 6 and the protrusions 7 are formed on the back surface 2e side of the crown portion 2 of the piston 1, a surface area of the whole back surface 2e is increased as compared with a case where no recessed portion 6 and no protrusions 7 are formed.
Because of this, a heat radiation effect in an area of the recessed portion 6 where the protrusions 7 are provided is increased, and cooling efficiency of the crown portion 2 and the piston 1 around the crown portion 2 can be promoted.
In particular, since a top end surface 7c of the protrusion 7 is formed into the arc shape, the surface area of the whole back surface 2e is increased, thereby further increasing the heat radiation effect.
In addition, each of the opposing inner side surfaces 6b and 6b at the long side of the recessed portion 6 and each of the opposing inner side surfaces 6c and 6c at the short side of the recessed portion 6 are formed into the arc shape that extends downward from the bottom surface 6a, and each outer peripheral edge 6d is connected to the arc-shaped upper wall surfaces 8a, 8b, 9a and 9b not smoothly, but stepwise. Therefore, by these structures, a surface area of the area of the recessed portion 6 is increased, and a good heat radiation effect can be obtained, then the cooling efficiency can be improved.
As a casting mold 10 for casting the piston 1, as shown in
The mold 11 is provided with a runner (or a pouring duct) 15 to pour molten metal into the cavity 14. This runner 15 has, at an upstream side thereof, a pouring opening 15a. A downstream portion 15b of the runner 15 communicates with a lower side of the cavity 14.
The core 12 is a portion that molds the crown surface 2a, the skirt portions 3a and 3b and the apron portions 4a and 4a of the piston 1 in cooperation with an inner surface of the mold 11 and a lower surface 13a of the top core 13.
That is, as shown in
As shown in
The protruding portion 19 is formed throughout the upper end surface 16a of the center core 16, and a plurality of groove portions 20 to form the protrusions 7 on the back surface 2e side of the crown portion 2 are formed on this upper surface (the upper end surface 16a). That is, the groove portions 20 are divided into two groups each formed from four groove portions 20 at both philip core 17 sides on opposite sides of a rectangular middle upper end surface 19a of the protruding portion 19. Each of the groove portions 20 is formed into a linear shape along a width direction of the protruding portion 19 between the both side cores 18 and 18. Further, each of the groove portions 20 is formed into a substantially arc shape in cross section. Furthermore, a depth D1 of each groove portion 20 is set to be shallower than the height H2 of the protruding portion 19. Openings 20a and 20b are formed at both end portions in an axial direction of the groove portion 20.
The top core 13 is placed so as to be able to open and close an upper end opening lla of the mold 11 by a hoisting and lowering machine formed by a cylinder etc.
(not shown) and so as to mold the crown surface 2a of the crown portion 2 by a cavity surface 13a that is a lower end surface of the top core 13.
That is, the cavity surface 13a of the top core 13, which faces the core 12, is formed as a transcription surface to transfer the crown surface 2a of the piston 1 when pouring the molten metal of the aluminium alloy into the cavity 14 and molding the piston 1 as a product.
The top core 13 is provided, at an upper end portion outer periphery thereof, a flange portion 13b that is formed integrally with the top core 13 so that when a core body of the top core 13 enters the mold 11 from the upper end opening 11a by the hoisting and lowering machine, by the fact that the flange portion 13b contacts an upper end opening edge of the mold 11, a further movement of the top core 13 is restrained or limited.
[Casting method for Piston]
To cast the piston 1 using the casting mold 10, the cores 16 to 18 of the core 12 are clamped together in the mold 11. Subsequently, as shown in
After this clamping, as shown in
With this pouring, as shown in
Afterwards, as shown in
That is, in this state, the aluminium alloy molten metal 21 is in absolute contact with the inner surface of the mold 11, an outer surface of the core 12 and the cavity surface 13a of the top core 13, and these shapes are transferred.
Especially in the present embodiment, the aluminium alloy molten metal 21 is poured into the cavity 14 from the pouring opening 15a through the runner 15, and flows into the cavity 14 from the lower side of the cavity 14. Here, an area or a part at the crown portion 2 side in the cavity 14 is an area or a part where flows of the aluminium alloy molten metal 21 meet and incomplete casting (or bad casting), e.g. poor flow of the molten metal, which is caused by the fact that air is captured and remains in the aluminium alloy molten metal 21, tends to occur.
However, in the present embodiment, as described above, although the aluminium alloy molten metal 21 flows into each of the groove portions 20, the aluminium alloy molten metal 21 does not flow into the groove portions 20 from the upper end opening side by flowing over the protruding portion 19 as shown by a broken line arrow in
Therefore, the air does not enter an area or a part between the aluminium alloy molten metal 21 and the bottom surface 20c in each groove portion 20, and the aluminium alloy molten metal 21 is immediately in absolute contact with the whole inner surface including the bottom surfaces 20c of the groove portions 20. Good transcription performance of the shape can therefore be obtained. It is consequently possible to sufficiently secure a surface area of each of the protrusions 7 formed by each of the groove portions 20.
Further, the aluminium alloy molten metal 21 after flowing into each groove portion 20 spreads or extends throughout an outer surface of the protruding portion 19 so as to gradually cover the entire outer surface of the protruding portion 19 while keeping the absolute contact with the outer surface of the protruding portion 19. It is therefore possible to secure a large surface area of an inner surface of the recessed portion 6 formed by the protruding portion 19.
Here, after finishing filling the cavity 14 with the aluminium alloy molten metal 21 and cooling the aluminium alloy molten metal 21 for a predetermined time, the casting mold 10 is opened, and base material of the piston 1 is taken out (a taking-out process).
Afterwards, by mechanically cutting surfaces etc. of the piston base material, a molding work of the piston 1 shown in
As explained above, according to the piston 1 of the present embodiment, the surface area of the back surface 2e of the crown portion 2 is increased by the recessed portion 6. Especially regarding the protrusion 7, since each of the protrusions 7 formed in the recessed portion 6 has no influence of the air in the casting process and the transcription performance can be obtained, a large surface area of the protrusion 7 can be secured. Accordingly, the heat radiation effect of the crown portion 2 is increased together with the heat radiation effect of the recessed portion 6. As a consequence, the cooling efficiency of the crown portion 2 can be improved.
Further, as explained above, the outer peripheral edge 6d of each of the inner side surfaces 6b, 6b, 6c and 6c of the recessed portion 6 is connected to the arc-shaped upper wall surfaces 8a, 8b, 9a and 9b not smoothly, but stepwise. Therefore, also by these structures, the surface area of the area of the recessed portion 6 is increased. Hence, the surface area of the whole back surface 2e is increased also by the increase of the surface area of the protrusion 7, thereby obtaining good heat radiation effect and promoting the cooling efficiency.
Furthermore, according to the piston production device and the piston production method, an orientation of a longitudinal direction of each of the groove portions 20 is set along the width direction of the protruding portion 19, and each of the openings 20a and 20b is formed so as to face the both side cores 18 and 18 along which the aluminium alloy molten metal 21 gradually rises. Moreover, the height of the bottom surface 20c of each of the groove portions 20 is set to a higher position than the upper end surfaces of the philip cores 17 and 17 and the side cores 18 and 18. Thus, the aluminium alloy molten metal 21 easily flows into each of the groove portions 20.
Consequently, since flowing performance of the aluminium alloy molten metal 21 into the groove portions 20 is improved and the air does not remain in the groove portions 20, it is possible to mold the protrusions 7 accurately.
With this, since a large surface area of the protrusion 7 can be secured, the heat radiation effect is further increased, and the cooling efficiency can be further improved.
In addition, only by providing the protruding portion 19 at the center core 16 and setting the depth D1 of each groove portion 20 to be lower than the height of the protruding portion 19, high accuracy of the surface is ensured with the influence of the air removed. This thus facilitates the molding work, and reduces a cost.
Further, since each of the groove portions 20 is formed into the linear shape along the direction of the apron portions 4a and 4a, the molten metal can be easily filled. The reason of this is because when pouring the aluminium alloy molten metal 21 into the mold, although the aluminium alloy molten metal 21 gradually rises from a gravity direction lower side, at a stage where the crown portion 2 is formed, a speed with which the aluminium alloy molten metal 21 gathers toward the middle of the crown portion 2 from directions of the apron portions 4a and 4a is greater than that from directions of the skirt portions 3a and 3b. That is, since the crown portion 2 at the apron portions 4a and 4a sides are formed earlier, the aluminium alloy molten metal 21 flows into the groove portions 20 earlier, then the good transcription performance of the shape of each of the protrusions 7 by each of the groove portions 20 can be obtained.
That is, on the back surface 2e side of the crown portion 2 of the piston 1, the rectangular recessed portion 6 extending between the skirt portions 3a and 3b, which is the same as the first embodiment, is formed, and two groups of the protrusion 7, each of which has three protrusions 7, are formed at right and left sides on opposite sides of the middle portion of the recessed portion 6. The protrusions 7 are arranged parallel to each other in three rows with a predetermined width clearance S2 provided between them. Each of the protrusions 7 is formed so as to extend along the longitudinal direction of the recessed portion 6, i.e. along an arrangement direction of the pair of thrust-side skirt portion 3a and anti-thrust-side skirt portion 3b. Although the number of the protrusions 7 is smaller than that of the first embodiment, each of the protrusions 7 has a long length, then a large surface area is secured.
The other structures or configurations, such as the height of the protrusion 7 which is set to be lower than the depth of the recessed portion 6, are the same as those of the first embodiment.
Further, the piston production method and the piston production device of this piston 1 are the same as those of the first embodiment, except that an arrangement and the number of the groove portions 20 to mold the protrusions 7 are different from those of the first embodiment. Therefore, the present embodiment can obtain the same working and effects as those of the first embodiment.
That is, two protrusion groups at right and left sides are formed at an inner side of the recessed portion 6 formed on the back surface 2e side of the crown portion 2 of the piston 1. Each of the protrusions 7 is formed so that a length of the protrusion 7 is short. The protrusions 7 in each group are arranged parallel to each other in five lines along a direction of the pin boss portions 4b and 4b, and also arranged parallel to each other in two rows along a direction of the skirt portions 3a and 3b. With this arrangement, the bottom surface 6a of the recessed portion 6 forms a grid pattern or a lattice pattern.
Therefore, although this embodiment can obtain the same working and effects as those of the first and second embodiments, a surface area of the grid-patterned (or the lattice-patterned) bottom surface 6a of the recessed portion 6 is greater than that of the other embodiments. Also, a surface area of each protrusion 7 itself is greater than that of the other embodiments. Thus, the heat radiation effect also becomes greater. As a result, the cooling efficiency of the crown portion 2 can be further improved.
Therefore, this embodiment can also obtain the same working and effects as those of the other embodiments. Further, since each of the protrusions 7 is formed into the arc shape, a surface area of the protrusion 7 is slightly greater than that of the linear protrusion 7 of the first embodiment. Thus, the heat radiation effect of the crown portion 2 becomes greater.
Therefore, this embodiment can also obtain the same working and effects as those of the other embodiments. Further, since the protrusions 7 are formed into the angle bracket shape and the reverse-angle bracket shape, a surface area of the protrusion 7 is slightly greater than that of the linear protrusion 7 of the first embodiment. Thus, the heat radiation effect of the crown portion 2 becomes greater.
The present invention is not limited to the above embodiments. For instance, a shape of the protrusion 7 could be further changed, and the number of the protrusions 7 could be changed. In addition, a size or a depth of the recessed portion 6 could be arbitrarily set according to specifications of the piston.
Further, in the embodiments, the height of the protrusion is set to be lower than the depth of the recessed portion. However, the height of the protrusion could be set to be the substantially same as the depth of the recessed portion.
Technical ideas that can be understood from the embodiment described above will be explained below.
A distance between adjacent two protrusions among the plurality of protrusions could be set to be larger than that between the other adjacent two protrusions. According to this invention, by providing a portion where the distance between the adjacent two protrusions is larger, this portion can be used as a method of measuring a thickness of the crown portion.
Each of the plurality of protrusions could be formed into an arc shape. According to this invention, since each of the plurality of protrusions is formed into the arc shape, as compared with the linear protrusion, a surface area of the protrusion can be greater.
The arc-shaped protrusion might be formed into a bulged shape or a convex shape formed by being curved radially outwards. According to this invention, since the protrusion has the bulged shape or the convex shape formed by being curved radially outwards, a space is created in the middle of the curved protrusion. It is therefore possible to overlap a measurement point of a thickness of the crown portion at this space.
Each of the plurality of protrusions could be formed into a wedge shape. According to this invention, a surface area of the protrusion can be greater than the case where each of the plurality of protrusions is formed into the linear shape.
The plurality of protrusions could be formed into a bulged shape or a convex shape formed by being curved radially outwards. According to this invention, since a space is created in the middle of the curved protrusion, by this space, a thickness of the crown portion can be measured. That is, a top end of the protrusion can overlap a measurement point of the crown portion.
The plurality of protrusions could be formed into a grid pattern or a lattice pattern extending in an axial direction of the piston pin holes of the apron portions of the recessed portion and in a direction orthogonal to this axial direction.
The other cores except the center core could be cores that mold inner surfaces of the skirt portions and the apron portions.
The lower mold could be a mold that is separated by moving the other cores by a close distance in a space created after moving the center core down, in the process in which the piston is taken out from the cavity by separating the mold. By employing this mold-separating method, even if an undercut portion is present at the piston, the mold can be separated without a hitch. Further, since the protrusions are placed in the recessed portion, even if the other cores are moved together in a close direction, the other cores do not interfere with the protrusions.
Number | Date | Country | Kind |
---|---|---|---|
2014-243619 | Dec 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2015/078980 | 10/14/2015 | WO | 00 |