JPH0144766Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to a cylinder block for an engine, and in particular to an improvement in the structure for cooling between the cylinder bores.

(Prior Art) Generally, in a cylinder block of a multi-cylinder engine, in order to prevent the temperature of the portion between the cylinder bores from rising to a high temperature due to heat generation in the combustion chambers in the cylinders on both sides, the portion between the cylinder bores is It is necessary to circulate cooling water through the However, the distance between the cylinder bores is extremely small, about 10-odd millimeters in a miniaturized engine, and it has therefore been difficult to efficiently cool the space between the cylinder bores with cooling water.

Therefore, conventionally, as disclosed in, for example, Japanese Utility Model Publication No. 52-54682, a cylinder block is provided with a structure in which the bores intersect with each other in an X-shape when viewed from the direction of the cylinder row. By drilling a large number of diagonal holes as cooling water passages, the amount of cooling water flowing into the inter-bore cooling water passages can be increased, and the cooling efficiency of the portion between each cylinder bore can be improved. A cylinder block structure has been proposed.

(Problem to be solved by the invention) However, in the above proposal, each inter-bore cooling water passage is arranged in a direction perpendicular to the direction of flow of cooling water flowing in the water jacket, that is, the cylinder row direction. Therefore, it is difficult for the cooling water to flow into the inter-bore cooling water passages, and in reality, the expected effect cannot be obtained.

Furthermore, since the main flow of the cooling water flows at a position further downward than the portion between the cylinder bores, from this point of view as well, it cannot be expected that the cooling water will flow into the inter-bore cooling water passages at a high flow rate.

In view of these points, the present invention forcibly introduces the cooling water discharged from the existing cooling water chamber into the cooling water passage between each bore formed in the direction perpendicular to the cylinder row direction of the cylinder block. The object of the present invention is to increase the flow rate of cooling water in each inter-bore cooling water passage, thereby effectively cooling the portion of the cylinder block between the cylinder bores with a simple structure.

(Means for solving the problem) To achieve this purpose, the solution of the present invention is as follows:
Utilizing the oil cooler chamber formed in the side wall of the cylinder, a cooling water discharge hole is provided in the partition wall that partitions the oil cooler chamber and the water jacket to allow the cooling water to flow out from the oil cooler chamber. By making the holes correspond to the cooling water passages between the cylinder bores, the cooling water discharged into the water jacket from the cooling water discharge holes is forcibly introduced into the cooling water passages between the cylinder bores.

Specifically, in the structure of the present invention, a single water jacket is formed between the plurality of cylinder bores and the outer wall of the cylinder block, while an oil jacket is formed on the side wall of the cylinder block adjacent to the water jacket. In a cylinder block of an engine, a cooler chamber is formed, and a cooling water passage for guiding cooling water from a water pump is provided to each of the water jacket and oil cooler chamber,
An inter-bore cooling water passage is formed between each of the cylinder bores, extending in a direction perpendicular to the cylinder row when viewed from above the cylinder block, and having one end opening toward the oil cooler chamber.

Further, a cooling water discharge hole for the oil cooler chamber is provided in a partition wall of the cylinder block that partitions the water jacket and the oil cooler chamber so as to face an opening at one end of each of the inter-bore cooling water passages.

(Function) As a result, a part of the cooling water supplied from the water pump flows through the water jacket on the side of the cylinder bore and cools mainly the part parallel to the cylinder row direction of each cylinder bore, while the rest After the cooling water is introduced into the oil cooler chamber through the cooling water passage, it is discharged from the oil cooler chamber into the water jacket through the cooling water discharge hole in the partition wall between the oil cooler chamber and the water jacket.

In that case, an inter-bore cooling water passage extending in a direction perpendicular to the cylinder row when viewed from above is formed in the portion between each cylinder bore, and the opening of each inter-bore cooling water passage faces the cooling water discharge hole of the partition wall. Therefore, the cooling water discharged from each of the cooling water discharge holes into the water jacket goes straight toward the opening of the inter-bore cooling water passage corresponding to the cooling water discharge hole, and flows straight into the inter-bore cooling water. Flows into the passage. This flow of cooling water increases the flow rate of cooling water flowing through the inter-bore cooling water passage, making it possible to efficiently cool the portion between the cylinder bores and increasing the cooling efficiency.

In addition, since the opening of the inter-bore cooling water passage corresponds to the cooling water discharge hole, when drilling the inter-bore cooling water passage from outside the cylinder block, the opening between the oil cooler chamber and the water jacket can be removed. A hole is bored in the partition wall, and this hole can be used as it is as a cooling water discharge hole, and can be easily manufactured.

Furthermore, it is only necessary to change the position of the existing cooling water discharge hole, which is required to drain the cooling water inside the oil cooler chamber into the water jacket, so that it corresponds to the opening of the inter-bore cooling water passage, which is inexpensive. can be produced.

(Example) Hereinafter, an example of the present invention will be described based on the drawings.

1 to 4, reference numeral 1 denotes a cylinder block of a four-cylinder engine according to an embodiment of the present invention, and the cylinder block 1 has four cylindrical cylinder bores 2, 2 extending in the vertical direction constituting the cylinder. ,... are formed in series at equal intervals. In the lower part between the cylinder bores 2, 2, ... and the outer wall of the cylinder block 1, there are a pair of water jets that allow cooling water pumped from a water pump (not shown) to flow in the direction of the cylinder row through a cooling water passage. Kets 3 and 4 are formed.

Further, a recess 5 that is open to the side of the cylinder block 1 is formed in one side wall portion of the cylinder block 1 at a portion corresponding to the one water jacket 3, and the recess 5 is connected to an oil cooler via a gasket 6. The recess 5 and the oil cooler cover 7 form an oil cooler chamber 8 adjacent to the water jacket 3. An oil cooler 9 having heat dissipating plates 9a, 9a, . It communicates with the oil gear gallery 11 in 1. Further, a cooling water passage 12 is formed in the side wall of the cylinder block 1 along one of the water jackets 3 to guide cooling water from the water pump to the oil cooler chamber 8. A partition wall between the cooler chamber 8 and the water jacket 3 is formed with cooling water discharge holes 13, 13, . The engine oil is supplied under pressure from an oil cooler (not shown) to an oil cooler 9, cooled by cooling water introduced into an oil cooler chamber 8, and then sent to an oil gear gallery 11. . Incidentally, reference numeral 14 denotes an oil filter attached to the oil cooler cover 7, which filters the engine oil cooled by the oil cooler 9.

Furthermore, an inter-bore cooling water passage 15 extending in a direction perpendicular to the cylinder row when viewed from above the cylinder block 1 is formed in the portion between each cylinder bore 2, and one end (inflow end) of the inter-bore cooling water passage 15.
opens into the water jacket 3 in the direction toward the oil cooler chamber 8, and the other end (outflow end) communicates with a cooling water passage 17 in the cylinder head 16. The cooling water discharge holes 13, 13, . . . are provided so as to face one end opening 15a of each of the inter-bore cooling water passages 15, respectively.

Therefore, in the above embodiment, most of the cooling water pumped from the water pump flows through the water jackets 3, 4 on the side of the cylinder bores 2, 2, . Cool the part parallel to the direction. On the other hand, the remaining cooling water is introduced into the oil cooler chamber 8 through the cooling water passage 12, and then from the oil cooler chamber 8 and the cooling water passage 12 through the cooling water discharge holes 13, 13, . During this period, the oil cooler 9 is cooled in the oil cooler chamber 8.

In this case, inter-bore cooling water passages 15, 15, .
Since one end opening 15a of each of the inter-bore cooling water passages 15 faces each of the cooling water discharge holes 13, the cooling water is discharged from each of the cooling water discharge holes 13 into the water jacket 3 at a high flow velocity. The cooling water flows straight toward an opening 15a at one end of each inter-bore cooling water passage 15 corresponding to each cooling water discharge hole 13, and flows into each inter-bore cooling water passage 15 from the opening 15a, After passing through the inter-bore cooling water passage 15, it flows out into the cooling water passage 17 of the cylinder head 16 from the opening at the other end. As a result, the flow rate of cooling water flowing through each inter-bore cooling water passage 15 increases, and as a result, the portion between each cylinder bore 2 and 2 can be efficiently cooled, and the cooling efficiency can be increased. .

In addition, one end opening 1 of each inter-bore cooling water passage 15
5a and each cooling water discharge hole 13 to face each other,
When forming the above-mentioned inter-bore cooling water passages 15 from outside the cylinder block 1 by drilling or the like, they are bored in the partition wall between the cooling water passages 12 and the oil cooler chamber 8 and one of the water jackets 3. The hole can be used as it is as the cooling water discharge hole 13, and therefore manufacturing can be carried out easily.

Furthermore, the existing cooling water discharge holes 13, which are necessary for draining the cooling water inside the oil cooler chamber 8 and inside the cooling water passage 12 into the water jacket 3,
13,..., respectively, to the cooling water passage 1 between each bore.
It only needs to be changed so that it corresponds to the opening 15a at one end of 5, and it can be manufactured at low cost.

In the above embodiment, the case where the present invention is applied to the cylinder block 1 of a four-cylinder engine has been described, but it goes without saying that the present invention can also be applied to the cylinder block of a multi-cylinder engine other than a four-cylinder engine. .

(Effects of the invention) As explained above, according to the invention, in the cylinder block of a multi-cylinder engine having an oil cooler chamber in the side wall, the cooling water passage between each cylinder bore is connected to the cylinder row when viewed from above the cylinder block. A cooling water discharge hole is formed in a partition wall between the oil cooler chamber and the water jacket so as to extend in a direction perpendicular to the oil cooler chamber, and one end thereof is opened toward the oil cooler chamber. By arranging it so as to face the opening at one end of the inter-bore cooling water passage, the cooling water discharged from the oil cooler chamber to the water jacket through the cooling water discharge hole is forcibly introduced into the inter-bore cooling water passage. As a result, the amount of cooling water flowing into each inter-bore cooling water passage increases, which is a practical advantage in that the existing structure can be used to inexpensively and easily improve the cooling efficiency for the portion between the cylinder bores. It shows the effectiveness.

[Brief explanation of drawings]

The drawings show an embodiment of the present invention; FIG. 1 is an exploded perspective view of an oil cooler mechanism installed in a cylinder block, FIG. 2 is a cross-sectional view of the cylinder block,
3 is an enlarged sectional view taken along the line -- in FIG. 2, and FIG. 4 is a view taken along the direction arrow in FIG. 1... Cylinder block, 2... Cylinder bore, 3, 4... Water jacket, 8... Oil cooler chamber, 9... Oil cooler, 12... Cooling water passage, 13... Cooling water discharge hole, 15... ...Inter-bore cooling water passage, 15a...opening.

Claims (1)

[Scope of utility model registration request] A single water jacket is formed between the plurality of cylinder bores and the outer wall of the cylinder block, while an oil cooler chamber is formed in the side wall of the cylinder block adjacent to the water jacket. In an engine cylinder block in which a cooling water passage for guiding cooling water from a water pump is provided in each oil cooler chamber, a passageway extending in a direction perpendicular to the cylinder row when viewed from above the cylinder block is provided between each of the cylinder bores, and one end is located above the cylinder bore. An inter-bore cooling water passage opening toward the oil cooler chamber is formed, and the water jacket and the oil cooler chamber are arranged so that the cooling water discharge hole of the oil cooler chamber faces one end opening of each inter-bore cooling water passage. A cylinder block for an engine, characterized in that the cylinder block is provided on a partition wall of the cylinder block that partitions the cylinder block.