JPS6329862Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) This invention relates to an engine cylinder block structure that improves cooling performance, and in particular eliminates heat accumulation between cylinder sections.

(Prior art) Outer peripheral wall 1 of cylinder block 10 shown in FIG.
In the case of a cylinder block of a multi-cylinder engine in which a cooling water passage 12 is formed between the cooling water passage 12 and the outer periphery of the cylinder portion 11, heat may accumulate in the cylinder portion 11a corresponding to the cylinder bore gap 13 through which cooling water is difficult to pass. Therefore, there is a risk of cracks occurring in this portion, which poses a problem of impairing the reliability and durability of the cylinder block 10. Furthermore, the portion 11a corresponding to the cylinder bore space 13 is higher than other portions and is offset, resulting in disadvantages such as poor fuel efficiency.

In order to eliminate the above drawbacks and improve the cooling performance especially between the cylinder bores,
No. 113105 proposes a cylinder block in which a pipe is provided on the bore wall between the cylinder bores to communicate the jackets on both sides along the bore row, thereby forming a bypass path for the cooling medium.

However, the above structure only has a pipe that communicates the jackets on both sides, and there is no means for forcing the cooling medium, that is, the cooling water, to be directed between the cylinder bores. It is difficult to pass through the pipe, therefore,
In practice, it has the disadvantage that cooling performance cannot be improved.

Regarding this problem of heat accumulation between cylinder bores, for example, as seen in Japanese Utility Model Application Publication No. 55-132315, a cooling water conduit is provided on one side of the cylinder row, and each adjacent cylinder part is connected to this cooling water conduit. It has been proposed that a nozzle hole for spouting cooling water is formed in the gap.

However, with such a configuration, a cooling water conduit must be provided separately within the cylinder block, resulting in an increase in the number of parts or a complicated structure of the cylinder block.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a cylinder block structure for an engine that is simple in construction and eliminates heat buildup between cylinder sections.

(Means and effects for achieving the technical problem) In order to achieve the above technical problem, in the present invention, the cooling water passage in the cylinder block passes through the gap between adjacent cylinder parts, and A main cooling water passage that meanderes cooling water in the longitudinal direction of the cylinder block from one outer wall side of the cylinder part to the other outer wall side of the other cylinder part, and the main cooling water passage of each of the cylinder parts. consists of a sub-cooling water passage provided at least in the upper part of the opposite outer wall side and having upstream and downstream ends communicating with the main cooling water passage, and the passage area of the sub-cooling water passage is set to be equal to or smaller than that of the main cooling water passage. It is configured to be smaller than the area.

That is, the present invention focuses on the passage area of the cooling water passage in the cylinder block, and in adjacent cylinder parts, one cylinder part has a cooling water passage on one outer wall side, and the other cylinder part has a cooling water passage on the other outer wall side.
Each sub-cooling water passage has a relatively small passage area, and the main flow of cooling water in the cylinder block is forced to flow from one outer wall side to the other outer wall side through the gap between adjacent cylinder parts. It is designed to meander in the longitudinal direction of the cylinder block. The sub-cooling water passage is provided at least in the upper part of the cylinder part in consideration of heat distribution around the cylinder part.

(Example) Hereinafter, an example of this invention will be described according to the drawings.

In FIG. 1, reference numeral 1 indicates a cylinder block of an engine, and reference numeral 2 indicates a cylinder section of each cylinder. A cooling water passage 3 is formed between an outer peripheral wall 1a of the cylinder block 1 and an outer periphery of the cylinder section 2.

The cooling water passage 3 passes along the longitudinal direction of the cylinder block 1 through one outer wall side 2a of each cylinder part 2 as shown by solid arrow A and the gap 2b between the cylinder bores, that is, the adjacent cylinder parts 2. A main cooling water passage 3a meandering in the direction, and a sub-cooling water provided on the other outer wall side 2c of each cylinder portion 2 as shown by the dotted arrow B, and whose upstream and downstream sides communicate with the main cooling water passage 3a. As is clear from FIG. 2, the auxiliary cooling water passage 3b is provided at the upper part of the cylinder portion 2, and its passage area is set smaller than that of the main cooling water passage 3a. There is. In the figure, 4 is the cylinder head, 5 is the piston, 6 is the exhaust valve, 7 is the intake valve, 8 is the cooling water passage 3 of the cylinder block 1, and the cylinder head 4.
A part of the cooling water in the cooling water passage 3 of the cylinder block 1 is supplied to the cooling water passage 9 of the cylinder head 4 through the communication hole 8. It's summery.

In the above configuration, since the passage area of the auxiliary cooling water passage 3b is set to be smaller than the passage area of the main cooling water passage 3a of the cooling water passage 3, the resistance to the cooling water flow naturally occurs in the auxiliary cooling water passage 3b. is larger. Therefore, a large amount of cooling water flows into the main cooling water passage 3a which meanders in the longitudinal direction of the cylinder block 1 through the gaps 2b between adjacent cylinder parts 2. That is, due to the fluid resistance generated in the sub-cooling water passage 3b, the cooling water is forcibly directed toward the gap 2b and actively flows.
The cooling performance of the cylinder section 2 corresponding to the above is improved.

Therefore, the local overheating phenomenon of the cylinder part 2 corresponding to the gap 2b disappears, and the heat distribution in the circumferential direction of the cylinder part 2 is made uniform, thereby preventing cracks in the cylinder part 2 and improving fuel efficiency. be able to.
Moreover, since the sub-cooling water passage 3b passes through the upper part of the cylinder part 2 which requires the most cooling, it can be made efficient and preferable.

(Effects of the invention) As explained above, this invention has a simple structure of changing the passage area, and the cooling water flowing inside the cylinder block is controlled by the passage resistance of the sub-cooling water passage, which has a relatively small passage area. , the cooling water is forcibly directed to the main cooling water passage passing through each cylinder gap. Therefore, there is an advantage that the cooling performance of the gap in the cylinder section, which is particularly prone to overheating, can be significantly improved.

Moreover, since the sub-cooling water passage is provided at least in the upper part of the cylinder part, the cooling performance of the upper part of the cylinder part, which has a large thermal load, is not hindered.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional plan view showing the cylinder block of an engine that resisted this idea, FIG. 2 is a cross-sectional view taken along the - line in FIG. 1, and FIG. 3 is a cross-sectional plan view of a conventional example. 1: Cylinder block, 1a: Outer peripheral wall, 2: Cylinder part, 2a: One outer wall side, 2b: Gap,
2c: Other outer wall side, 3: Cooling water passage, 3a:
Main cooling water passage, 3b: sub-cooling water passage.

Claims (1)

[Claims for Utility Model Registration] In a cylinder block structure for a multi-cylinder engine in which a cooling water passage is formed between the outer peripheral wall of the cylinder block and the outer periphery of the cylinder part, the cooling water passage is connected between adjacent cylinder parts. A main cooling water passage that meanderes cooling water in the longitudinal direction of the cylinder block from one outer wall side of one cylinder section to the other outer wall side of the other cylinder section through the gap, and A sub-cooling water passage is provided at least in the upper part of the outer wall opposite to the main cooling water passage, and the upstream and downstream ends thereof communicate with the main cooling water passage, and the passage area of the sub-cooling water passage is set as above. An engine cylinder block structure characterized by having a passage area smaller than that of a main cooling water passage.