(1) Field of the Invention
The present invention relates to an engine cooler.
(2) Description of Related Art
A conventional engine cooler employs an open-deck structure in some cases in which the upper face of the water jacket is fully opened and thus, readily allows the piston slap sound to pass toward a cylinder head.
The piston slap sound readily occurs.
In such a cooler that employs the open-deck structure in which the upper face of the water jacket is fully opened, the piston slap sound readily passes toward the cylinder head, emitting the piston slap sound.
An object of the present invention is to provide an engine cooler capable of suppressing the piston slap sound.
Through studies, inventors of the present invention found that arrangement of a pressed member between the cylinder barrel and the spacer on lateral sides of the cylinder barrel can suppress the piston slap sound to device the present invention.
Matters specifying the invention according to the present invention are as follows.
An engine cooler includes a cylinder block having a cylinder barrel and a water jacket, and a spacer stored in the water jacket,
the water jacket surrounds the cylinder barrel, and the spacer encloses the cylinder barrel,
the engine cooler further includes a pressed member,
given that a width direction of the cylinder block is a lateral direction, the pressed member is pressed between the cylinder barrel and the spacer on lateral sides of the cylinder barrel, and
a lower end of the pressed member is disposed above a lower end of each of right and left skirts of a piston located at a top dead center.
The present invention has a following effect.
The piston slap sound can be suppressed.
The piston slap sound is suppressed. The reason can be assumed as follows: the piston slap sound caused near the lower ends of the right and left skirts by the oscillation of the piston is insulated by the pressed member and is hard to pass toward the cylinder head, suppressing the piston slap sound.
The backlash sound of the spacer can be eliminated.
The spacer is firmly fixed to the cylinder barrel via the pressed member, eliminating the backlash sound of the spacer.
This engine cooler will be summarized below.
As shown in
As shown in
The cylinder block (3) is an aluminum die casting, and the inner circumferential face of the cylinder barrel (1) (1) is casted with an iron cylinder liner (1a). The water jacket (2) has an open-deck structure in which the upper side is fully opened.
An outward expanding section (1c) (1c) of the cylinder barrel (1) (1) is a strike plate of an injection hole cap (not shown) of an auxiliary chamber. A cooling-water introducing gap (3a) is provided in an upper part between cylinder bores.
As shown in
As shown in
Therefore, the piston slap sound is suppressed.
The reason can be assumed as follows: the piston slap sound caused near the lower ends (7a) of the right and left skirts (7) by the oscillation of the piston (6) is insulated by the pressed member (5) and is hard to pass toward the cylinder head, suppressing the piston slap sound.
Further, the spacer (4) is firmly fixed to the cylinder barrel (1) (1) via the pressed member (5) (5), eliminating the backlash sound of the spacer (4).
As shown in
Therefore, the piston slap sound can be highly suppressed.
The reason can be assumed as follows. That is, a large slap sound caused near the piston maximum-diameter section (7b) by the oscillation of the piston (6) is insulated by the pressed member (5) and is hard to pass toward the cylinder head, suppressing the piston slap sound.
As shown in
Therefore, the effect of suppressing the piston slap sound is high.
The reason can be assumed as follows. That is, the piston slap sound caused near the front end (7c) of each of the right and left skirts (7) of the piston (6) by the oscillation of the piston (6) is insulated by the front end (5b) of the pressed member (5), which is located in front of the front end (7c) of the skirt (7), and is hard to pass toward the cylinder head and further, the piston slap sound caused near the rear end (7d) of each of the right and left skirts (7) of the piston (6) is insulated by the rear end (5c) of the pressed member (5), which is located in the rear of the rear end (7d) of the skirt (7), and is hard to pass toward the cylinder head. Therefore, the effect of suppressing the piston slap sound is high.
As shown in
Therefore, heat radiated from the pressure ring (9) can be prevented from being blocked by the pressed member (5).
As shown in
Therefore, heat radiated from the oil ring (10) can be prevented from being blocked by the pressed member (5).
The pressed member (5) is made of an elastomeric resin. Specifically, the pressed member (5) is made of a urethane foam. The pressed member (5) may be made of rubber (including foamed rubber) in addition to a resin (including foamed resin). That is, the pressed member (5) just has to be made of a cushion material. Therefore, the effect of suppressing the piston slap sound is high. The reason can be assumed as follows: since the piston slap sound caused near the lower end (7a) of the skirt (7) of the piston (6) by the oscillation of the piston (6) is absorbed by the pressed member (5) made of the elastomeric resin or rubber, the effect of suppressing the piston slap sound is high.
The pressed member (5) is attached to the spacer (4). The attachment is performed by adhesion. Therefore, mere pressing the spacer (4) to which the pressed member (5) is attached to the water jacket (2) can pressingly sandwich the pressed member (5) (5) between the cylinder barrel (1) (1) and the spacer (4), thereby easily attaching the spacer (4) and the pressed member (5) (5) to the cylinder barrel (1) (1).
The spacer (4) is made of a resin. Specifically, the spacer (4) is made of nylon. The spacer (4) may be made of PPA (polyphthalamide). The spacer (4) may be made of rubber (for example, butyl rubber).
The spacer (4) may be made of a resin (including foamed resin), rubber (including foamed rubber), or a material obtained by forming a rubber layer (4d) on the surface of resin or a metal base material (4c). That is, the spacer (4) just has to be made of an acoustic absorption material. Therefore, the piston slap sound tends to be absorbed by the material of the spacer (4) and thus, the effect of suppressing the piston slap sound is high.
The spacer (4) can be constituted by forming a heat insulating layer (4e) in the base material (4c). Therefore, the heat retaining property of the cylinder barrel (1) (1) is high, increasing the warm-up speed at start of cooling.
As shown in
Number | Date | Country | Kind |
---|---|---|---|
2014-056380 | Mar 2014 | JP | national |
Number | Name | Date | Kind |
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20030230254 | Matsutani | Dec 2003 | A1 |
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20090194046 | Shikida | Aug 2009 | A1 |
20110114042 | Hamakawa | May 2011 | A1 |
Number | Date | Country |
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8628188 | Dec 1986 | DE |
10102644 | Feb 2002 | DE |
2002030989 | Jan 2002 | JP |
2005201084 | Jul 2005 | JP |
2007002822 | Jan 2007 | JP |
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20090063995 | Jun 2009 | KR |
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Entry |
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Extended EP Search Report dated Jul. 17, 2015 in EP Application No. 15157340.9. |
Office Action issued Aug. 1, 2017 in JP Application No. 2014-056380. |
Examination Report issued Jul. 25, 2017 in EP Application No. 15157340.9. |
Number | Date | Country | |
---|---|---|---|
20150267636 A1 | Sep 2015 | US |