JPH05272336A - Cooling water circulation device for engine - Google Patents

Abstract

PURPOSE:To flow much cooling water into a cooling water path between cylinder bores to thereby cool between the bores efficiency whose heat load is high by providing the cooling water path between the bores through which an intake side of a cylinder block cooling water path is communicated with an exhaust side thereof, between the cylinder bores, and providing a means of promoting cooling between the bores. CONSTITUTION:A cooling water circulation apparatus R is provided in which cooling water flows through an intake side cylinder head cooling water path, an intake side 8a and an exhaust side 8b of a cylinder block cooling water path 8 and an exhaust side cylinder head cooling water path, and thus an intake port is cooled efficiency. Cooling water path 22, 23 between bores are provided through which the intake side 8a is communicated with the exhaust side 8b. A water passing part and water passing holes whose cross sectional areas are large and which distribute much cooling water are provided around intake side ends of the cooling water paths 22, 23 between the bores. According to this constitution, the parts between the cylinder bores 5 whose heat load is high are cooled efficiency.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine cooling water circulating device.

[0002]

2. Description of the Related Art Generally, a vehicle engine is provided with a cooling device in order to keep the engine temperature below a heat-resistant limit temperature. In the cooling device for a water-cooled engine, cooling water passages are provided in the cylinder head and the cylinder block, respectively, and the engine is cooled by flowing cooling water through these cooling water passages.

In a conventional engine, the heat load between the cylinder bores in the cylinder block is particularly high. Therefore, in the conventional engine cooling device, the cooling water cooled by the radiator is first transferred to the cylinder block cooling water passage. The cooling water in the cylinder block cooling water passage is supplied into the cylinder head cooling water passage through the water passage hole formed in the gasket. The cooling water in the cylinder head cooling water passage is sent to the radiator to be cooled and supplied again to the cylinder block cooling water passage. Further, in order to improve the cooling performance between the cylinder bores of the cylinder block, there has been proposed an engine cooling device in which a water supply hole is formed in a gasket at a position corresponding to the cylinder bore. (For example, the actual exploitation 63
-111985 publication).

[0004]

However, in the conventional cooling device in which the cooling water is made to flow from the cylinder block cooling water passage to the cylinder head cooling water passage,
There is a problem that the temperature of the cooling water flowing into the cylinder head cooling water passage becomes relatively high, the air in the intake port is heated by this high-temperature cooling water, and the maximum output of the engine decreases due to the decrease in filling efficiency. It was Therefore, the passage cross-sectional area of the water intake hole on the intake side of the gasket is made larger than the passage cross-sectional area of the water passage on the exhaust side to increase the flow rate of the cooling water flowing through the intake side portion of the cooling water passage. There has been proposed an engine cooling device which suppresses the temperature rise of the internal air (see Japanese Utility Model Laid-Open No. 62-14118).

Further, the cooling water cooled by the radiator is
First, the engine cooling device that supplies the cooling water in the cylinder head cooling water passage and supplies the cooling water in the cylinder head cooling water passage to the cylinder block cooling water passage to suppress the temperature rise of the air in the intake port is provided. Proposed
(See, for example, Japanese Utility Model Laid-Open No. 1-125816).

However, when the cooling water is made to flow from the cylinder head cooling water passage to the cylinder block cooling water passage, the temperature of the cooling water flowing into the cylinder block cooling water passage becomes high, so that the cooling between the cylinder bores becomes very difficult. become worse. In addition, the above-mentioned actual development Sho 63-11985
As in the cooling device disclosed in Japanese Unexamined Patent Publication (Kokai) No. 0-242, if the water supply holes for cooling the cylinder bores are provided or the inter-bore cooling water passages are formed between the cylinder bores, the cooling between the cylinder bores is promoted to some extent. Since there is almost no driving force or water pressure difference for circulating the cooling water in the inter-bore cooling water passage, it is difficult to effectively cool the space between the cylinder bores. . It should be noted that if the bore pitch (cylinder bore interval) is increased, cooling between the cylinder bores is promoted, but there is a problem that the total length of the engine becomes long.

The present invention has been made in order to solve the above-mentioned conventional problems, and effectively cools between the cylinder bores having a high heat load without causing the temperature rise of the air in the intake port. It is an object of the present invention to provide an engine cooling device or a cooling water circulating device capable of achieving the above.

[0008]

To achieve the above object, a first aspect of the present invention provides an intake side cylinder head cooling water passage and an exhaust side cylinder head cooling water passage formed in a cylinder head and a cylinder block. A cooling water supply system having a cylinder block cooling water passage formed so as to surround the cylinder row is provided, and the cooling water supply system is configured such that the cooling water in the intake side cylinder head cooling water passage is a cylinder block cooling water passage. A cooling water circulation device for an engine, which is formed so as to flow into the exhaust side cylinder head cooling water passage after flowing into the cylinder block cooling water passage, and connects the intake side portion and the exhaust side portion of the cylinder block cooling water passage between the cylinder bores. An inter-bore cooling water passage is provided and the cooling water flowing from the intake side cylinder head cooling water passage into the cylinder block cooling water passage is Part of the water, forcing to provide cooling water circulation system for an engine, characterized in that the bore between the cooling promoting means to cool the entire cylinder block after circulating the inter-bore cooling water passage is provided.

According to a second aspect of the present invention, in the engine cooling water circulation device according to the first aspect, the water passage hole for communicating the cooling water passage in the cylinder head with the cylinder block cooling water passage is, in plan view, a cylinder bore. Between the inter-cylinder bore area and the inter-cylinder bore area, and the passage cross-sectional areas of the water passage holes arranged in the inter-cylinder bore area are set to be larger than the passage cross-sectional areas of the water passage holes arranged in other areas, and the intake side Provided is a cooling water circulating device for an engine, wherein a passage cross-sectional area of a water passage hole arranged in the area is set to be larger than a passage cross-sectional area of a water passage hole arranged in the exhaust side area.

According to a third aspect of the present invention, in the engine cooling water circulating device according to the first aspect, between the intake side portion and the exhaust side portion of at least one of both ends of the cylinder block cooling water passage in the cylinder arrangement direction. A cooling water circulation device for an engine, characterized in that a throttle portion for narrowing the cooling water circulation cross-section is formed.

According to a fourth aspect of the present invention, in the engine cooling water circulating device according to the first aspect, the intake side cylinder head cooling water passage is extended closer to the spark plug than the exhaust side cylinder head cooling water passage. An engine cooling water circulation device is provided.

[0012]

EXAMPLES Examples of the present invention will be specifically described below.
As shown in FIGS. 1 to 4, a cooling water circulation device R (cooling device)
In the water-cooled engine CE equipped with the cylinder block 1, the cylinder head 2 is arranged at the upper end of the cylinder block 1 via the gasket 3, and the cylinder block 1 and the cylinder head 2 are fastened with bolts that are screwed into bolt holes 4. (Not shown)
Has been concluded by.

In the cylinder block 1, each cylinder # 1
Cylinder bores 5 are provided at positions corresponding to # 3,
A crank chamber 6 is formed below each of these cylinder bores 5. A plurality of crank bearings 7 that rotatably support a crank shaft (not shown) are provided near the lower end of the cylinder block 1. A cylinder block cooling water passage 8 for cooling the cylinder block 1 is provided in the cylinder block 1. Further, in the cylinder block 1, a cooling water receiving port 9 for receiving cooling water supplied from a radiator (not shown) and a cooling water flowing into the cooling water receiving port 9 are guided to the cylinder head 2 side. A cooling water guide passage 10 is provided. Here, the cooling water inlet 9 and the cooling water guide passage 10 merely guide the cooling water to the cylinder head 2 side, and do not particularly have a function of cooling the cylinder block 1. The cylinder block cooling water passage 8, the cooling water receiving port 9 and the cooling water guide passage 10 form a part of the cooling water circulating device R.

On the lower surface of the cylinder head 2, each cylinder # 1
To # 3 are respectively formed with recesses 12 which are coupled with the corresponding cylinder bores 5 to define combustion chambers. In addition, in the cylinder head 2, a plug hole 13 for accommodating a spark plug (not shown), two intake ports 14, for each cylinder # 1 to # 3,
Two exhaust ports 15 are provided. Further, in a planar positional relationship, the plug hole 13 has the recess 1
2, the intake port 14 opens in the intake side half of the recess 12 (the left half in FIG. 4), and the exhaust port 15 opens.
Is open to the exhaust side half of the recess 12 (right half in FIG. 4). Furthermore, in the cylinder head 2, the valve stem
A valve stem accommodating portion 16 for accommodating (not shown) and a camshaft bearing portion 17 for rotatably supporting a camshaft (not shown) are formed.

A cylinder head cooling water passage 19 for cooling the cylinder head 2 is provided in the cylinder head 2. The cylinder head cooling water passage 19 includes an intake side cylinder head cooling water passage 19a located on the intake side. It is partitioned into an exhaust side cylinder head cooling water passage 19b located on the exhaust side. Here, the intake side cylinder head cooling water passage 1
9a is extended toward the vicinity of the plug hole 13 (ignition lug, lug) so that the periphery of the plug hole 13 having a high heat load can be sufficiently cooled. The intake-side cylinder head cooling water passage 19a communicates with the cooling water guide passage 10 in the cylinder block 1 through the cooling water introduction passage 18, so that the cooling water cooled by the radiator sequentially receives the cooling water. First, it is supplied to the intake side cylinder head cooling water passage 19a via the inlet 9, the cooling water guide passage 10 and the cooling water introduction passage 18. Further, the cooling water in the exhaust side cylinder head cooling water passage 19b is discharged from the cooling water discharge port 20 to the radiator side. The cooling water introduction passage 18, the cylinder head cooling water passages 19a and 19b, and the cooling water discharge port 20 form a part of the cooling water circulation device R.

In the cooling water circulation device R, the cooling water is basically supplied from the intake side cylinder head cooling water passage 19a to the intake side portion 8a of the cylinder block cooling water passage 8.
(See FIG. 5) → Exhaust side portion 8b of the cylinder block cooling water passage 8 (see FIG. 5) → Exhaust side cylinder head cooling water passage 1
It is designed to flow in the order of 9b. Hereinafter, as shown in FIGS.
A mechanism for generating such a cooling water flow will be described in detail with reference to FIG.

As shown in FIG. 5, the cylinder block cooling water passage 8 is formed in such a shape as to surround the circumference of the cylinder row, and basically, except for the vicinity of both ends in the cylinder row direction, the intake side portion 8a. It is partitioned from the exhaust side portion 8b. Then, between the cylinder bores of the cylinders # 1 and # 2, in order to effectively cool the space between the cylinder bores, a first inter-bore cooling water passage that connects the intake side portion 8a and the exhaust side portion 8b by cross drilling is provided. 22 is formed. Similarly, a second inter-bore cooling water passage 23 is formed between the cylinder bores of the cylinders # 2 and # 3.

A first throttle portion 24 is formed at the front end portion (left end portion in FIG. 5) of the cylinder block cooling water passage 8 for narrowing the cooling water flow cross section between the intake side portion 8a and the exhaust side portion 8b. Similarly, a second throttle portion 25 is formed at the rear end portion (right end portion in FIG. 5). These throttle parts 24 and 25 are
The flow of cooling water from the intake side portion 8a to the exhaust side portion 8b at both ends in the cylinder row direction is throttled, and the inter-bore cooling water passage 22,
It is provided to increase the circulation amount of the cooling water of 23.

As shown in FIG. 6, in the cylinder head 2, a plurality of intake sides for guiding the cooling water in the intake side cylinder head cooling water passage 19a to the intake side portion 8a of the cylinder block cooling water passage 8 are provided. Water passages 26 to 30 are provided. Here, each of the intake side water passage portions 27, 28, 29 is formed to have an elongated passage cross section, and the passage cross sectional area is set to be considerably large. In this, the intake side water passage portions 28 and 29 enter the region between the cylinder bores. In addition, the passage cross-sectional areas of the other intake side water passage portions 26, 30 are set to be relatively small. Further, in the cylinder head 2, a plurality of exhaust side water passage portions 31 to 40 for guiding the cooling water in the exhaust side portion 8b of the cylinder block cooling water passage 8 to the exhaust side cylinder head cooling water passage 19b.
Is provided. The passage cross-sectional areas of these exhaust-side water passage portions 31 to 40 are set to be relatively small.

As shown in FIG. 7, the gasket 3 has a plurality of intake side passages for communicating the intake side water passage portions 26 to 30 in the cylinder head 1 with the intake side portion 8a of the cylinder block cooling water passage 8. Water holes 42-48 and cylinder head 1
A plurality of exhaust side water passage holes 31 to 40 are formed to connect the exhaust side water passage portions 31 to 40 and the exhaust side water passage portions 8b of the cylinder block cooling water passage 8 to each other. These water passage holes 42 to 48, 51 to 60 preferably regulate the flow or distribution of the cooling water in the cylinder block 1 or the cylinder head 2 as described below.

The intake-side water passage holes 44 and 46 arranged between the cylinder bores are, in a planar positional relationship, the intake-side portions of the inter-cylinder bore regions, that is, the first and second inter-bore cooling water passages 22 and 23, respectively. It is located near the intake side end of the. The passage cross-sectional areas of both intake side water passage holes 44 and 46 are set to be considerably larger than those of the other water passage holes. Therefore, the cooling water flowing from the cylinder head side to the cylinder block side is distributed mainly to the vicinity of the intake side end portions of the interbore cooling water passages 22 and 23 by the intake side water passage holes 44 and 46. For this reason, the water pressure at the intake side end portions of the both-bore cooling water passages 22 and 23 becomes high, and therefore the differential pressure between both end portions of the both-bore cooling water passages 22 and 23 becomes large, and the both-bore cooling water passages become large. A large amount of cooling water is forcibly passed through the inside of the cylinders 22 and 23, so that the space between the cylinder bores having a high heat load is cooled very effectively. Further, the cooling water immediately after flowing in from the cylinder head side, that is, the cooling water of a relatively low temperature that has not yet contacted with the cylinder block body,
Since it is supplied to the cooling water passages 22 and 23 between the both bores, the cooling between the cylinder bores is further promoted.

Further, the water passage portions 26 to 30, 31 to 40,
When the water passage holes 42 to 48 and 51 to 60 are viewed as a whole, the passage cross-sectional area on the intake side is larger than the passage cross-sectional area on the exhaust side. The entire flow of cooling water from 8a to the exhaust side portion 8b is assisted, and cooling of the cylinder block 1 is promoted. Both intake side water passage holes 44, 46 or both throttle portions 24, 25 correspond to the "inter-bore cooling promoting means" described in claim 1.

In the cooling water circulation device R, since the low temperature cooling water cooled by the radiator is first supplied to the intake side cylinder head cooling water passage 19a, the intake port 14 is effectively cooled and the charging efficiency is improved. The maximum output of the engine is increased. Also, as mentioned above,
Since the intake-side cylinder head cooling water passage 19a extends to the vicinity of the plug hole 13, the area around the plug hole having a high heat load is effectively cooled. Further, the differential pressure between both ends of the inter-bore cooling water passages 22, 23 becomes large, and the throttle portions 24, 2 are provided at the front and rear ends of the cylinder block cooling water passage 8.
5, the inter-bore cooling water passages 22, 23 are formed.
A large amount of cooling water can be passed to the cylinder bores, and the space between the cylinder bores with high heat load can be effectively cooled.

[0024]

According to the first aspect of the present invention, the low-temperature cooling water cooled by the radiator is first supplied to the intake-side cylinder head cooling water passage, so that the intake port is effectively cooled and the intake air is cooled. The temperature rise of the air in the port is suppressed,
The filling efficiency is improved. Moreover, since a large amount of cooling water is passed through the inter-bore cooling water passage by the inter-bore cooling promoting means, the space between the cylinder bores having a high heat load is effectively cooled, and the reliability of the engine is enhanced.

According to the second invention, basically, the same operation and effect as those of the first invention can be obtained. Furthermore, since the passage cross-sectional area of the water passage holes located in the region between the cylinder bores on the intake side is set large and the water pressure of the cooling water near this water passage hole becomes high, the difference between the two ends of the inter-bore cooling water passage is increased. The pressure increases, the amount of cooling water flowing through the inter-bore cooling water passage becomes very large, and cooling between the cylinder bores is further promoted.

According to the third invention, basically, the same operation and effect as those of the first invention can be obtained. Furthermore, since the flow of cooling water at the two ends of the cylinder block cooling water passage in the cylinder row direction is throttled by the throttle portion, the amount of cooling water flowing through the inter-bore cooling water passage increases, and cooling between the cylinder bores is further promoted. It

According to the fourth invention, basically, the same operation and effect as those of the first invention can be obtained. Further, since the intake side cylinder head cooling water passage is extended to the vicinity of the spark plug, cooling around the spark plug having a high heat load is promoted.

[Brief description of drawings]

FIG. 1 is an elevational side sectional view of an engine equipped with a cooling water circulation device according to the present invention.

FIG. 2 is a cross-sectional view taken along the line AA of the engine shown in FIG.

FIG. 3 is a cross-sectional view taken along the line BB of the engine shown in FIG.

FIG. 4 is a cross-sectional view taken along the line CC of the engine shown in FIG.

FIG. 5 is an explanatory plan view of a cylinder block.

FIG. 6 is an explanatory plan view of a cylinder head.

FIG. 7 is an explanatory plan view of a gasket.

[Explanation of symbols]

 CE ... Engine R ... Cooling water circulation device 1 ... Cylinder block 2 ... Cylinder head 3 ... Gasket 5 ... Cylinder bore 8 ... Cylinder block cooling water passage 8a ... Intake side portion 8b ... Exhaust side portion 13 ... Plug hole 19a ... Intake side cylinder head cooling Water passage 19b ... Exhaust side cylinder head cooling water passage 22, 23 ... First and second bore cooling water passage 24, 25 ... First and second throttle portions 26-30 ... Intake side water passage portion 31-40 ... Exhaust Side water passage part 42-48 ... Intake side water passage hole 51-60 ... Exhaust side water passage hole

Claims (4)

[Claims] 1. An intake side cylinder head cooling water passage and an exhaust side cylinder head cooling water passage formed in a cylinder head, and a cylinder block cooling water passage formed so as to surround a cylinder row in a cylinder block. A cooling water supply system is provided, and the cooling water supply system is
A cooling water circulating device for an engine, wherein cooling water in an intake side cylinder head cooling water passage is formed so as to flow into a cylinder block cooling water passage and then into an exhaust side cylinder head cooling water passage. An inter-bore cooling water passage that connects the intake side portion and the exhaust side portion of the cylinder block cooling water passage is provided, and part of the cooling water that has flowed into the cylinder block cooling water passage from the intake side cylinder head cooling water passage is An inter-bore cooling promoting means for cooling the entire cylinder block after forcibly circulating the inter-bore cooling water passage, is provided. 2. The engine cooling water circulation device according to claim 1, wherein the water passages communicating the cooling water passages in the cylinder head and the cylinder block cooling water passages with the inter-cylinder bore region in plan view. The passage cross-sectional area of the water passage hole provided in the outer region between the cylinder bores and arranged in the inter-cylinder bore region is
The passage cross-sectional area of the water passage hole, which is set larger than the passage cross-sectional area of the water passage hole arranged in the other area, and which is arranged in the intake side region, is larger than the passage cross-sectional area of the water passage hole arranged in the exhaust side region. The engine cooling water circulation device is also characterized in that it is set to a large size. 3. The engine cooling water circulation device according to claim 1, wherein the cooling water between the intake side portion and the exhaust side portion is provided on at least one of both ends of the cylinder block cooling water passage in the cylinder arrangement direction. A cooling water circulation device for an engine, wherein a throttle portion for narrowing a circulation cross section is formed. 4. The engine cooling water circulation device according to claim 1, wherein the intake side cylinder head cooling water passage is extended to a position near the spark plug rather than the exhaust side cylinder head cooling water passage. Engine cooling water circulation device.