JP5939176B2 - Multi-cylinder engine cooling structure - Google Patents

Description

  The present invention relates to a cooling structure for a multi-cylinder engine.

  In a vehicle equipped with a multi-cylinder engine, generally, a water jacket is formed in which the coolant flows in the cylinder block and cylinder head of the multi-cylinder engine, and the coolant is applied to the cylinder block and the water jacket of the cylinder head from one end side of the cylinder row of the cylinder block. Is introduced to cool the cylinder bore.

  In addition, the coolant introduced into the water jacket of the cylinder block and the cylinder head is heated by cooling the cylinder bore, and this warmed coolant is discharged from the other end of the cylinder row of the cylinder head to the radiator. In general, the coolant cooled by the radiator is again introduced into the water jacket of the cylinder block from one end side of the cylinder row of the cylinder block by the water pump, and the coolant is circulated.

  In this way, when cooling liquid is introduced into the cylinder block and the water jacket of the cylinder head from one end side of the cylinder row of the cylinder block to cool the cylinder bore, the upper part of the cylinder block in the vicinity of the combustion chamber is lower than the lower part for each cylinder. Therefore, a temperature difference is generated in the vertical direction of the cylinder bore. When a temperature difference occurs in the vertical direction of the cylinder bore, the inner surface of the cylinder bore is deformed, and wear on the piston ring and the inner surface of the cylinder bore is increased due to local friction with the piston ring, thereby suppressing the temperature difference in the vertical direction of the cylinder bore. It is desirable to do.

  On the other hand, for example, Patent Document 1 discloses a partition member including a spacer having a vertical wall surface surrounding cylinder bores of a plurality of cylinders and a flow path separating member coupled to the upper portion of the spacer in a water jacket of a cylinder block. There is disclosed a system in which the coolant introduced from one end side of the cylinder row is divided in the vertical direction to suppress the temperature difference in the vertical direction of the cylinder bore.

Japanese Patent No. 4845620

  Although the thing of the patent document 1 can suppress the temperature difference of the up-down direction of a cylinder bore, since it becomes high temperature on the exhaust side about each cylinder compared with the intake side, it is temperature on the intake side and exhaust side of a cylinder bore. There will be a difference. If there is a temperature difference between the intake side and the exhaust side of the cylinder bore, the inner surface of the cylinder bore is deformed and wear on the piston ring and cylinder bore due to local friction with the piston ring increases. It is desirable to suppress the temperature difference on the exhaust side.

  Further, in the multi-cylinder engine, when the coolant is introduced from one end side of the cylinder row, the cooling performance is lowered because the coolant is warmed on the other end side of the cylinder row as compared to the one end side of the cylinder row. There will be a temperature difference between the cylinder bores in the row direction. Since the temperature difference between the cylinder bores causes non-uniformity in the sliding resistance of the piston and the wear state of the cylinder bore inner surface for each cylinder, it is desirable to suppress the temperature difference between the cylinder bores.

  Accordingly, an object of the present invention is to provide a cooling structure for a multi-cylinder engine that can reduce the temperature difference between the intake side and the exhaust side of the cylinder bore, the temperature difference in the vertical direction, and the temperature difference between the cylinder bores.

  In order to solve the above problems, the present invention is configured as follows.

First, the invention according to claim 1 of the present application includes a water jacket provided in a cylinder block so as to surround cylinder bores of a plurality of cylinders arranged in series, and a water jacket provided in a cylinder head. A cooling structure for a multi-cylinder engine equipped with a coolant path for circulating coolant through these water jackets and radiators by a pump, and cooling to the water jacket of the cylinder block on one end side of the cylinder row An introduction portion for introducing liquid is provided, and a spacer having a vertical wall surface surrounding the cylinder bores of the plurality of cylinders is inserted into the water jacket of the cylinder block, and the vertical wall surface of the spacer includes A throttle that restricts the flow of coolant to the intake side of the water jacket in the vicinity; A step portion forming an upper flow passage having a larger flow passage cross-sectional area than a lower portion at an upper portion of an exhaust side portion of the water jacket, and a flow of the coolant in the upper flow passage at the other end side of the cylinder row a guide portion for guiding with directing to the intake-side portion so as to direct to the cylinder head side, is provided, et al is, the narrowed portion, the vertical wall surface of the to be close to the outer wall of the water jacket of the cylinder block An upper restricting portion protruding outward from the upper portion and an outer wall portion of the water jacket of the cylinder block are separated from the lower portion of the vertical wall surface so that a part of the coolant flows to the intake side portion of the water jacket. And a lower restricting portion protruding smaller than the upper restricting portion, and the spacer surrounds a cylinder bore of a cylinder adjacent to the lower restricting portion. A flange portion extending outward from the vertical wall surface is provided at the lower end portion of the vertical wall surface so as to be close to the outer wall portion of the water jacket of the cylinder block, and is connected to an intake side portion of the water jacket of the cylinder block. A discharge portion for discharging the coolant from the center side of the cylinder row is provided, and the discharge portion is provided on the lower side of the outer wall portion of the water jacket of the cylinder block, and the coolant discharged from the discharge portion flows. A heat exchanger is interposed in the coolant path .

Further, the invention according to claim 2 of the present application is the invention according to claim 1, wherein the upper flow path extends from one end side of the cylinder row to the other end side of the cylinder row and the upper portion of the vertical wall surface of the spacer. Formed between the outer wall of the water jacket of the cylinder block, the stepped portion projects from the one end side of the cylinder row to the other end side of the cylinder row, and the lower portion of the vertical wall surface projects outward as compared to the upper portion. It is characterized by being formed.

  Further, the invention according to claim 3 of the present application is the invention according to claim 2, wherein the vertical wall surface is disposed on the intake side portion of the water jacket and the outer wall of the water jacket of the cylinder block. A width between the vertical portion and the outer wall portion of the water jacket of the cylinder block is formed to be larger than a width between the vertical wall surface disposed at a lower portion of the exhaust side portion of the water jacket, The guide portion is a rib formed to protrude outward from the vertical wall surface so as to be close to the outer wall portion of the water jacket of the cylinder block.

  With the above configuration, according to the invention of each claim of the present application, the following effects can be obtained.

  First, according to the invention according to claim 1 of the present application, the vertical wall surface of the spacer inserted into the water jacket of the cylinder block is connected to the intake side portion of the water jacket in the vicinity of the introduction portion provided on one end side of the cylinder row. A throttle portion that restricts the flow of the coolant, a step portion that forms an upper passage having a larger passage cross-sectional area than the lower portion at the upper portion of the exhaust side of the water jacket, and an upper passage at the other end of the cylinder row And a guide portion that guides the coolant to flow toward the intake side of the water jacket and toward the cylinder head.

  As a result, the coolant introduced from one end side of the cylinder row by the throttle portion can flow more to the exhaust side portion than to the intake side portion of the water jacket, so that the temperature becomes higher than that on the intake side of the cylinder bore. The cooling performance on the exhaust side of the cylinder bore can be improved, and the temperature difference between the intake side and the exhaust side of the cylinder bore can be reduced.

  In addition, since the coolant introduced from one end side of the cylinder row by the step portion can flow more in the upper part of the exhaust side portion of the water jacket than in the lower part, the temperature of the cylinder bore that becomes higher than that in the lower part of the cylinder bore The cooling performance of the upper part can be improved, and the temperature difference in the vertical direction of the cylinder bore can be reduced.

Furthermore, the cooling performance of the coolant introduced from one end side of the cylinder row and flowing over the exhaust side portion of the water jacket is reduced on the other end side of the cylinder row, but the exhaust side portion of the water jacket is lowered by the guide portion. The coolant flowing in the upper part of the cylinder row can be U-turned to the intake side portion of the water jacket on the other end side of the cylinder row and reliably flow, so that the cooling performance of the cylinder bore on the other end side of the cylinder row can be improved. The temperature difference between the cylinder bores in the cylinder row direction can be reduced. In addition, since the coolant flowing in the upper part of the exhaust side portion of the water jacket can be reliably flowed to the cylinder head side, the cooling performance of the cylinder head can also be improved.
Furthermore, the throttle portion is spaced apart from the upper throttle portion projecting outward from the upper portion of the vertical wall surface so as to be close to the outer wall portion of the water jacket of the cylinder block, and the outer wall portion of the water jacket of the cylinder block. A part of the cooling liquid introduced from one end side of the cylinder row is made into a water by being composed of a lower throttle part protruding outward from the lower part of the vertical wall so that a part of the cooling liquid flows to the intake side part. Since it can flow to the intake side portion of the jacket, the cooling performance on the intake side and the exhaust side of the cylinder bore by the coolant introduced from one end side of the cylinder row can be adjusted, and the above effect can be more effectively achieved. it can.
The spacer further includes a flange portion extending outward from the vertical wall surface so as to be close to the outer wall portion of the water jacket of the cylinder block at the lower end portion of the vertical wall surface surrounding the cylinder bore of the cylinder adjacent to the lower throttle portion. As a result, coolant having high cooling performance introduced from one end of the cylinder row and flowing to the intake side portion of the water jacket flows between the vertical wall surface of the spacer and the inner wall portion of the water jacket of the cylinder block from below the spacer. Thus, it is possible to prevent the lower portion of the cylinder bore from being excessively cooled, and to suppress an increase in the temperature difference in the vertical direction of the cylinder bore.
Still further, by providing a discharge portion that is connected to the intake side portion of the water jacket of the cylinder block and discharges the coolant from the center side of the cylinder row, the coolant introduced from one end side of the cylinder row is It is possible to reliably flow from one end side of the cylinder row to the other end side at the upper portion of the exhaust side portion of the water jacket, and then to the intake side portion of the water jacket at the other end side of the cylinder row, thereby achieving the effect more effectively. Can do.

According to the invention of claim 2 of the present application, the upper flow path includes the upper part of the vertical wall surface of the spacer and the outer wall part of the water jacket of the cylinder block from one end side of the cylinder row to the other end side of the cylinder row. The step portion is relatively simple because the lower part of the vertical wall surface protrudes outward from the upper part from one end side of the cylinder row to the other end side of the cylinder row. With this configuration, the temperature difference in the vertical direction of the cylinder bore can be reduced.

  Further, according to the invention according to claim 3 of the present application, the vertical wall surface has a width between the vertical wall surface disposed on the intake side portion of the water jacket and the outer wall portion of the water jacket of the cylinder block. Formed to be larger than the width between the vertical wall located at the lower part of the exhaust side and the outer wall of the water jacket of the cylinder block, and the guide is close to the outer wall of the water jacket of the cylinder block As described above, the rib formed so as to protrude outward from the vertical wall surface can reduce the temperature difference between the cylinder bores in the cylinder row direction with a relatively simple configuration.

It is a figure which shows typically the cooling structure of the multicylinder engine which concerns on embodiment of this invention. It is a figure which shows the cylinder block of the multicylinder engine which concerns on embodiment of this invention, a spacer, and a gasket. It is a perspective view which shows the cylinder block in which the spacer was inserted. It is sectional drawing of the said cylinder block along the Y4-Y4 line | wire in FIG. It is sectional drawing of the said cylinder block along the Y5-Y5 line | wire in FIG. It is sectional drawing of the said cylinder block along the Y6-Y6 line | wire in FIG. It is a perspective view which shows a spacer. It is the perspective view of the spacer seen from the A direction in FIG. It is a top view of a spacer. It is a front view of a spacer. It is a rear view of a spacer. It is a left view of a spacer. It is a right view of a spacer. It is sectional drawing of the spacer along the Y14-Y14 line | wire in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a diagram schematically showing a cooling structure of a multi-cylinder engine according to an embodiment of the present invention. In FIG. 1 and FIGS. 2 to 6 which will be described later, with respect to the cylinder block and the cylinder head, the intake side is represented as IN and the exhaust side is represented as EX.

  As shown in FIG. 1, a cooling structure 1 for a multi-cylinder engine according to an embodiment of the present invention is provided in a cylinder block 20 so as to surround cylinder bores 21 of a plurality of cylinders # 1 to # 4 arranged in series. A water jacket 22 and a water jacket 32 provided on the cylinder head 30 are provided. The water pump 3 causes the water pump 3 to pass through the water jackets 22 and 32 and the radiator 4 for cooling the coolant. A circulating coolant path L is provided.

  In the present embodiment, the multi-cylinder engine 2 is an in-line four-cylinder engine in which four cylinders # 1, # 2, # 3, and # 4 are arranged in series, and the cylinder block 20 includes four cylinders # 1 to # 1. A water jacket 22 is formed in an annular shape so as to surround the # 4 cylinder bore 21.

  The cylinder block 20 is formed with an introduction portion 23 for introducing the coolant into the water jacket 22 of the cylinder block 20 on one end side of the cylinder row, specifically, on the first cylinder # 1 side. The cylinder block 20 is also formed with a discharge portion 24 that is connected to the intake side portion of the water jacket 22 and discharges the coolant from the center side of the cylinder row.

  The cylinder block 20 and the cylinder head 30 are coupled with a gasket 50 shown in FIG. The water jacket 22 of the cylinder block 20 and the water jacket 32 of the cylinder head 30 communicate with each other through a communication hole 52 formed in the gasket 50.

  Thereby, a part of the coolant introduced into the water jacket 22 of the cylinder block 20 on one end side of the cylinder row flows into the water jacket 32 of the cylinder head 30 through the communication hole 52, and the remaining part of the coolant passes through the discharge part 24 to the cylinder. It is discharged from the water jacket 22 of the block 20.

  The water jacket 32 of the cylinder head 30 covers the entire circumference of the cylinder row from one end side to the other end side of the cylinder row so as to cover the periphery of the intake port, exhaust port, plug port (not shown), etc. of each cylinder # 1 to # 4. It is formed over.

  The cylinder head 30 has a first discharge portion 33 and a second discharge portion 34 that discharge the coolant from the water jacket 32 of the cylinder head 30 to the other end side of the cylinder row, specifically, to the fourth cylinder # 4 side. Is formed. The coolant introduced from the water jacket 22 of the cylinder block 20 into the water jacket 32 of the cylinder head 30 is discharged from the other end side of the cylinder row.

  The coolant discharged from the first discharge portion 33 passes through the temperature detection unit 6 including a temperature detection sensor that detects the temperature of the coolant, and the coolant passage L1 that connects the first discharge portion 33 and the radiator 4. After flowing into the radiator 4 and being cooled by the radiator 4, it flows into the valve unit 5 through a coolant path L <b> 2 connecting the radiator 4 and the valve unit 5.

  The valve unit 5 includes a first flow rate control valve 5a, a second flow rate control valve 5b, a third flow rate control valve 5c, and a thermostat valve 5d, and the first, second and third flow rate control valves 5a, 5b, 5c are respectively provided. The flow rate of the coolant flowing through the first, second and third flow rate control valves 5a, 5b and 5c is controlled by the control device 15.

  In the present embodiment, the first, second, and third flow control valves 5a, 5b, and 5c are each set to an open state, but the first, second, and third flow control valves 5a, 5b, and 5c are The open / close control and the flow rate control can be performed based on the temperature of the coolant detected by the temperature detection sensor of the temperature detection unit 6. On the other hand, the thermostat valve 5d is configured to be opened when the temperature of the coolant in the thermostat valve 5d reaches a predetermined temperature.

  The coolant that has flowed to the valve unit 5 through the coolant path L2 that connects the radiator 4 and the valve unit 5 passes through the first flow rate control valve 5a and passes through the coolant path L3 that connects the valve unit 5 and the water pump 3. The water flows into the pump 3 and is introduced into the water jacket 22 of the cylinder block 20 by the water pump 3.

  The coolant discharged from the first discharge portion 33 also flows to the valve unit 5 through the temperature detection unit 6 and the coolant passage L4 connecting the first discharge portion 33 and the valve unit 5. The coolant path L4 and the coolant path L3 are connected by a thermostat valve 5d, and the coolant discharged from the first discharge unit 33 is also the temperature detection unit 6, the coolant path L4, the thermostat valve 5d, and the coolant. The water flows to the water pump 3 through the path L3 and is introduced into the water jacket 22 of the cylinder block 20 by the water pump 3.

  On the other hand, the coolant discharged from the second discharge portion 34 flows to the valve unit 5 through the coolant path L5 connecting the second discharge portion 34 and the valve unit 5. The coolant path L5 also includes an auxiliary water pump 7 that pumps the coolant in an auxiliary manner, a heater unit 8 that exchanges heat between the coolant and the air conditioning air, and a part of the exhaust gas to the intake side. An EGR cooler 9 for exchanging heat between the coolant in the EGR system to be recirculated and the exhaust gas recirculated to the intake side, and an EGR valve 10 for controlling the amount of coolant supplied to the EGR cooler 9 are provided. .

  The coolant that has flowed to the valve unit 5 through the coolant path L5 that connects the second discharge part 34 and the valve unit 5 is the coolant that connects the valve unit 5 and the water pump 3 through the third flow rate control valve 5c. The water flows to the water pump 3 through the path L3 and is introduced into the water jacket 22 of the cylinder block 20 by the water pump 3.

  Note that the coolant that flows to the valve unit 5 through the coolant path L5 that connects the second discharge part 34 and the valve unit 5 is also configured to flow to the thermostat valve 5d, and the coolant is predetermined in the thermostat valve 5d. When the temperature is above the temperature and the valve is in the open state, it flows to the water pump 3 through the thermostat valve 5d and the coolant path L3.

  In the present embodiment, a discharge portion 24 is formed in the cylinder block 20, and the coolant discharged from the discharge portion 24 of the cylinder block 20 is a cooling that connects the discharge portion 24 of the cylinder block 20 and the valve unit 5. It flows to the valve unit 5 through the liquid path L6. An oil cooler 11 that exchanges heat between the coolant and engine oil and an ATF warmer 12 that exchanges heat between the coolant and ATF, which is an automatic transmission oil, are also provided in the coolant path L6. Has been.

  The coolant that has flowed to the valve unit 5 through the coolant path L6 that connects the discharge part 24 of the cylinder block 20 and the valve unit 5 flows to the water pump 3 through the coolant flow path L3 through the second flow rate control valve 5b. The pump 3 introduces the water jacket 22 of the cylinder block 20.

  Thus, the multi-cylinder engine cooling structure 1 according to the present embodiment includes the water jacket 22 provided in the cylinder block 20 and the water jacket 32 provided in the cylinder head 30, and the water pump 3 The coolant is circulated through the water jackets 22 and 32 and the radiator 4.

  FIG. 2 is a view showing a cylinder block, a spacer, and a gasket of the multi-cylinder engine according to the embodiment of the present invention. As shown in FIG. 2, in the multi-cylinder engine 2 according to the present embodiment, a spacer provided with a vertical wall surface 41 surrounding the cylinder bores 21 of the four cylinders # 1 to # 4 in the water jacket 22 provided in the cylinder block 20. 40 is inserted.

  Then, with the spacer 40 inserted into the water jacket 22 of the cylinder block 20, the gasket 50 is overlaid on the cylinder block 20, and the cylinder block 20 and the cylinder head 30 use fastening bolts (not shown) via the gasket 50. Are combined.

  The gasket 50 is provided with four openings 51 formed in a circular shape like the cylinder bore 21, and the coolant flows between the water jacket 22 of the cylinder block 20 and the water jacket 32 of the cylinder head 30. A communication hole 52 is provided to enable the above. In FIG. 2, the shape of the water jacket 22 of the cylinder block 20 is indicated by a two-dot chain line.

  The gasket 50 is provided with one communication hole 52 on the exhaust side of each of the four openings 51 formed corresponding to the four cylinders # 1 to # 4, and two cylinders # 2 on the center side of the cylinder row. 2 and # 3, one communication hole 52 is provided on each intake side of the two openings 51 formed corresponding to # 3, and four ends are provided on one end side of the cylinder row in which the introduction portion 23 of the cylinder block 20 is formed. A communication hole 52 is formed.

With reference to FIGS. 3 to 14, the cooling structure of the multi-cylinder engine according to the embodiment of the present invention will be described in more detail.
3 is a perspective view showing the cylinder block in which the spacer is inserted, FIG. 4 is a sectional view of the cylinder block along the line Y4-Y4 in FIG. 3, and FIG. 5 is along the line Y5-Y5 in FIG. FIG. 6 is a sectional view of the cylinder block taken along line Y6-Y6 in FIG.

  As shown in FIGS. 3 to 6, the spacer 40 inserted into the water jacket 22 of the cylinder block 20 includes a vertical wall surface 41 surrounding the cylinder bores 21 of the four cylinders # 1 to # 4. 22 between the inner wall portion 25 of the cylinder 22 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20. As shown in FIGS. 5 and 6, a wear resistant liner 27 is integrally formed on the inner wall portion 25 of the water jacket 22 of the cylinder block 20.

  7 is a perspective view showing the spacer, FIG. 8 is a perspective view of the spacer viewed from the direction A in FIG. 7, FIG. 9 is a top view of the spacer, FIG. 10 is a front view of the spacer, and FIG. FIG. 12 is a left side view of the spacer, FIG. 13 is a right side view of the spacer, and FIG. 14 is a sectional view of the spacer along the line Y14-Y14 in FIG.

  As shown in FIGS. 7 to 14, the vertical wall surface 41 of the spacer 40 is formed in an annular shape so as to surround the cylinder bores 21 of the four cylinders # 1 to # 4, and is formed so as to extend in the vertical direction. The vertical wall surface 41 is provided with a throttle portion 42 that restricts the flow of coolant to the intake side portion 22b of the water jacket 22 in the vicinity of the introduction portion 23 of the cylinder block 20 on the intake side on one end side of the cylinder row. Yes.

  The throttle portion 42 is formed to protrude outward from the vertical wall surface 41 in a substantially triangular shape in plan view, and has an upper throttle portion 42 a that protrudes outward from the upper portion of the vertical wall surface 42, and outward from the lower portion of the vertical wall surface 42. The lower diaphragm part 42b protrudes smaller than the upper diaphragm part 42a.

  As shown in FIG. 4, the upper throttle portion 42 a is provided so as to be close to the outer wall portion 26 of the water jacket 22 of the cylinder block 20, and the lower throttle portion 42 b is connected to the outer wall portion 26 of the water jacket 22 of the cylinder block 20. It is provided so as to be separated.

  The vertical wall surface 41 is also provided with an inclined portion 43 on one end side of the cylinder row for directing the coolant introduced from the introduction portion 23 of the cylinder block 20 to the upper portion of the exhaust side portion 22a of the water jacket 22. The inclined portion 43 extends from the lower portion of the vertical wall surface 41 on the intake side toward the exhaust side of the vertical wall surface 41 and is formed by a rib protruding outward from the vertical wall surface 41.

  The vertical wall surface 41 is also provided with a step 44 that forms an upper channel L11 having a larger channel cross-sectional area than the lower part at the upper part of the exhaust side portion 22a of the water jacket 22. The step portion 44 is formed such that the lower portion of the vertical wall surface 41 disposed on the exhaust side portion 22a of the water jacket 22 protrudes outward as compared to the upper portion.

  As shown in FIGS. 5 and 6, the vertical wall surface 41 disposed on the exhaust side portion 22 a of the water jacket 22 has a width between the upper portion of the vertical wall surface 41 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20. Is larger than the width between the lower portion of the vertical wall surface 41 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20.

  As a result, the flow passage cross-sectional area of the upper flow passage L11 through which the coolant formed between the vertical wall surface 41 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20 flows above the exhaust side portion 22a of the water jacket 22 is increased. Compared to the flow path cross-sectional area of the lower flow path L12 in which the coolant formed between the vertical wall surface 41 and the inner wall portion 25 of the water jacket 22 of the cylinder block 20 flows below the exhaust side portion 22a of the water jacket 22. It is greatly formed.

  In the spacer 40, a rib 45 extending in the vertical direction is formed inside a stepped portion 44 provided below the vertical wall surface 41. The rib 45 extends inward from the vertical wall surface 41 and is formed so that the tip of the rib 45 coincides with the upper portion of the vertical wall surface 41 as shown in FIG. 9.

  The vertical wall surface 41 also directs the coolant flow in the upper flow path L11 from one end side to the other end side of the cylinder row on the other end side of the cylinder row to the intake side portion 22a of the water jacket 22 and the cylinder head. A guide unit 46 is provided for guiding the projector 30 so as to be directed toward the 30 side.

  The guide portion 46 extends from the exhaust side to the intake side of the vertical wall surface 41 in an inclined manner continuously to the step portion 44 on the other end side of the cylinder row and surrounds the cylinder bore 21 of the fourth cylinder # 4. It is formed by ribs that extend continuously in the horizontal direction to the intake side of 41 and protrude outward from the vertical wall surface 41.

  The vertical wall surface 41 is also configured such that the width between the vertical wall surface 41 disposed on the intake side portion 22 b of the water jacket 22 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20 is the exhaust side portion 22 a of the water jacket 22. Is formed so as to be larger than the width between the vertical wall surface 41 disposed at the lower portion of the cylinder wall 20 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20.

  The vertical wall surface 41 of the spacer 40 also extends from the vertical wall surface 41 to the lower end of the vertical wall surface 41 surrounding the cylinder bore 21 of the cylinder adjacent to the lower throttle portion 42b, specifically, the first and second cylinders # 1 and # 2. A flange portion 47 extending outward is provided. The collar portion 47 is formed in a substantially trapezoidal shape in plan view according to the shape of the outer wall portion 26 of the water jacket 22 so as to be close to the outer wall portion 26 of the water jacket 22 of the cylinder block 20.

  The spacer 40 is integrally formed by injection molding using a material such as a polyamide-based thermoplastic resin.

Next, the flow of the coolant introduced into the water jacket 22 of the cylinder block 20 in which the spacer 40 is inserted will be described.
As shown in FIG. 7, the flow of the coolant introduced into the cylinder block 20 on one end side of the cylinder row is restricted by the throttle portion 42 to the intake side portion 22b of the water jacket 22 as indicated by an arrow S1. It mainly flows to the exhaust side portion 22a of the water jacket 22 and flows to the upper portion of the exhaust side portion 22a of the water jacket 22 by the inclined portion 43.

  As shown in FIG. 8, the coolant flowing to the upper part of the exhaust side portion 22a of the water jacket 22 is in the exhaust side portion 22a of the water jacket 22 in the order of arrows S2, S3, S4, S5 in the other end side of the cylinder row. Then, the step portion 44 mainly flows through the upper channel L11 having a larger channel cross-sectional area than the lower portion formed at the upper portion of the exhaust side portion 22 of the water jacket 22. The coolant that has flowed to the other end side of the cylinder row in the upper portion of the exhaust side portion 22a of the water jacket 22 flows to the intake side portion 22b of the water jacket 22 and the cylinder head 30 by the guide portion 46 as shown by an arrow S6. Flows to the side.

  The coolant flowing to the intake side portion 22b of the water jacket 22 at the other end side of the cylinder row and flowing to the cylinder head 30 side is the intake side of the water jacket 22 as shown by arrows S7 and S8 in FIGS. In the portion 22b, it flows to one end side of the cylinder row and flows to the cylinder head 30 side. The coolant that has flowed to the cylinder head 30 side flows to the water jacket 32 of the cylinder head 30 through the communication hole 52 of the gasket 50 as described above.

  In the present embodiment, the discharge portion 24 connected to the intake side portion 22b of the cylinder block 20 is formed on the center side of the cylinder row, so that the intake side portion 22b of the water jacket 22 has one end from the other end side of the cylinder row. A part of the coolant flowing to the side flows downward toward the discharge part 24 of the cylinder block 20 and is discharged from the discharge part 24 as indicated by an arrow S10.

  In the present embodiment, the coolant introduced into the cylinder block 20 on one end side of the cylinder row is restricted to flow to the intake side portion 22b of the water jacket 22 by the throttle portion 42, but constitutes the throttle portion 42. Since the lower restricting portion 42b is formed so as to be separated from the outer wall portion 26 of the water jacket 22 of the cylinder block 20, a part of the coolant introduced into the cylinder block 20 on one end side of the cylinder row is illustrated in FIG. 7 and FIG. 10, as indicated by arrows S <b> 11 and S <b> 12, the air flows to the intake side portion 22 b of the water jacket 22 and is discharged from the discharge portion 24.

  As described above, in the multi-cylinder engine cooling structure 1 according to the present embodiment, the introduction portion 23 provided on one end side of the cylinder row is provided on the vertical wall surface 41 of the spacer 40 inserted into the water jacket 22 of the cylinder block 20. In the vicinity, a restricting portion 42 for restricting the flow of the coolant to the intake side portion 22b of the water jacket 22 and an upper flow path L11 having a larger channel cross-sectional area than the lower portion are formed above the exhaust side portion 22a of the water jacket 22. And a guide portion 46 that guides the flow of the coolant in the upper flow path L11 toward the intake side portion 22b of the water jacket 22 and toward the cylinder head 30 side on the other end side of the cylinder row. Is provided.

  As a result, the coolant introduced from one end side of the cylinder row by the throttle portion 42 can flow more to the exhaust side portion 22a than to the intake side portion 22b of the water jacket 22, and therefore, compared to the intake side of the cylinder bore 21. Thus, the cooling performance on the exhaust side of the cylinder bore 21 that becomes high temperature can be improved, and the temperature difference between the intake side and the exhaust side of the cylinder bore 21 can be reduced.

  Further, since the coolant introduced from one end side of the cylinder row by the step portion 44 can flow more in the upper portion of the exhaust side portion 22a of the water jacket 22 than in the lower portion, the coolant temperature is higher than that in the lower portion of the cylinder bore 21. Thus, the cooling performance of the upper part of the cylinder bore 21 can be improved, and the temperature difference in the vertical direction of the cylinder bore 21 can be reduced.

  Furthermore, the cooling performance of the coolant introduced from one end side of the cylinder row and flowing through the upper portion of the exhaust side portion 22a of the water jacket 22 is reduced on the other end side of the cylinder row. The coolant flowing in the upper part of the exhaust side portion 22a can be made to U-turn to the intake side portion 22b of the water jacket 22 at the other end side of the cylinder row and flow reliably. The cooling performance can be improved, and the temperature difference between the cylinder bores 21 in the cylinder row direction can be reduced. In addition, since the coolant flowing in the upper part of the exhaust side portion 22a of the water jacket 22 can be surely flowed to the cylinder head 30 side, the cooling performance of the cylinder head 30 can also be improved.

  The upper flow path L11 is formed between the upper part of the vertical wall surface 41 of the spacer 40 and the outer wall part 26 of the water jacket 22 of the cylinder block 20, and the step part 44 has a lower part of the vertical wall surface 41 compared to the upper part. Accordingly, the temperature difference in the vertical direction of the cylinder bore 21 can be reduced with a relatively simple configuration.

  Further, the vertical wall surface 41 has a width between the vertical wall surface 41 disposed above the intake side portion 22 b of the water jacket 22 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20, and the exhaust side portion 22 a of the water jacket 22. The guide wall 46 is formed so as to be larger than the width between the vertical wall surface 41 arranged at the lower portion of the cylinder wall 20 and the outer wall portion 26 of the water jacket 22 of the cylinder block 20. Due to the ribs protruding outward from the vertical wall surface 41 so as to be close to the outer wall portion 26, the temperature difference between the cylinder bores 21 in the cylinder row direction can be reduced with a relatively simple configuration.

  Furthermore, the throttle portion 42 includes an upper throttle portion 42a that protrudes outward from the upper portion of the vertical wall surface 41 so as to be close to the outer wall portion 26 of the water jacket 22 of the cylinder block 20, and an outer wall of the water jacket 22 of the cylinder block 20. A portion of the coolant introduced from one end side of the cylinder row is made to be part of the water jacket 22 by being constituted by the lower throttle portion 42b protruding outward from the lower portion of the vertical wall surface 41 so as to be separated from the portion 26. Since the air can flow through the intake side portion 22b, the cooling performance of the intake side and the exhaust side of the cylinder bore 21 by the coolant introduced from one end side of the cylinder row can be adjusted.

  Further, the spacer 40 includes a collar portion 47 extending outward from the vertical wall surface 41 at the lower end portion of the vertical wall surface 41 surrounding the cylinder bores 21 of the cylinders # 1 and # 2 adjacent to the lower throttle portion 42b. Cooling liquid having high cooling performance introduced from one end side of the row and flowing to the intake side portion 22b of the water jacket 22 from the lower side of the spacer 40 and the inner wall portion 25 of the water jacket 22 of the cylinder block 20 It is possible to prevent the lower portion of the cylinder bore 21 from being excessively cooled by flowing between the above and the temperature difference in the vertical direction of the cylinder bore 21 from being increased.

  Still further, a discharge portion 24 that is connected to the intake side portion 22b of the water jacket 22 of the cylinder block 20 and discharges the coolant from the center side of the cylinder row is provided, so that it is introduced from one end side of the cylinder row. The coolant can reliably flow from one end side of the cylinder row to the other end side in the upper portion of the exhaust side portion 22a of the water jacket 22 and then to the intake side portion 22b of the water jacket 22 on the other end side of the cylinder row. The cooling performance of the cylinder bores 21 on the other end side of the row can be improved, and the temperature difference between the cylinder bores 21 in the cylinder row direction can be reduced.

  The present invention is not limited to the illustrated embodiments, and various improvements and design changes can be made without departing from the scope of the present invention.

  As described above, according to the present invention, in a multi-cylinder engine, the temperature difference between the intake side and the exhaust side of the cylinder bore, the temperature difference in the vertical direction, and the temperature difference between the cylinder bores can be reduced. There is a possibility of being suitably used in the manufacturing industry such as a vehicle equipped with a cylinder engine.

2 Multi-cylinder engine 3 Water pump 4 Radiator 20 Cylinder block 21 Cylinder bore 22 Cylinder block water jacket 22a Water jacket exhaust side portion 22b Water jacket intake side portion 23 Introducing portions 24, 33, 34 Discharge portion 26 Water jacket outer wall portion 30 Cylinder head 32 Cylinder head water jacket 40 Spacer 41 Vertical wall surface 42 Restriction part 42a Upper restriction part 42b Lower restriction part 44 Step part 46 Guide part 47 Brim part L Coolant path L11 Upper flow path # 1, # 2, # 3 , # 4 cylinder

Claims (3)

It has a water jacket provided on the cylinder block so as to surround the cylinder bores of a plurality of cylinders arranged in series and a water jacket provided on the cylinder head, and these water jacket and radiator are routed by a water pump. And a cooling structure for a multi-cylinder engine provided with a coolant path for circulating the coolant.
On one end side of the cylinder row, an introduction part for introducing the coolant into the water jacket of the cylinder block is provided,
A spacer having a vertical wall surface surrounding the cylinder bores of the plurality of cylinders is inserted into the water jacket of the cylinder block,
On the vertical wall surface of the spacer,
A throttle part that restricts the flow of the coolant to the intake side portion of the water jacket in the vicinity of the introduction part;
A stepped portion that forms an upper channel having a larger channel cross-sectional area than the lower part at the upper part of the exhaust side portion of the water jacket;
A guide portion for guiding to direct to the cylinder head side with directing the flow of the cooling liquid of the upper channel to the intake-side portion of the water jacket at the other end of the cylinder bank, is provided, et al is,
The throttle part is spaced apart from the upper throttle part projecting outward from the upper part of the vertical wall surface so as to be close to the outer wall part of the water jacket of the cylinder block and the outer wall part of the water jacket of the cylinder block. It is composed of a lower restricting portion that protrudes smaller than the upper restricting portion outward from the lower portion of the vertical wall surface so that a part of the coolant flows to the intake side portion of the jacket,
The spacer includes a flange portion extending outward from the vertical wall surface so as to be close to the outer wall portion of the water jacket of the cylinder block at a lower end portion of the vertical wall surface surrounding a cylinder bore of a cylinder adjacent to the lower throttle portion. And
A discharge portion connected to the intake side portion of the water jacket of the cylinder block is provided to discharge the coolant from the center side of the cylinder row, and the discharge portion is provided on the lower side of the outer wall portion of the water jacket of the cylinder block. And
A heat exchanger is interposed in the coolant path through which the coolant discharged from the discharge portion flows.
A cooling structure for a multi-cylinder engine. The upper flow path is formed between one end side of the cylinder row and the other end side of the cylinder row between the upper portion of the vertical wall surface of the spacer and the outer wall portion of the water jacket of the cylinder block, The lower portion of the vertical wall surface is formed so as to protrude outwardly from the upper portion from one end side of the cylinder row to the other end side of the cylinder row .
The multi-cylinder engine cooling structure according to claim 1. The vertical wall surface has a width between the vertical wall surface arranged at the upper part of the intake side portion of the water jacket and the outer wall portion of the water jacket of the cylinder block arranged at the lower part of the exhaust side portion of the water jacket. The guide wall is formed so as to be larger than a width between the vertical wall surface and the outer wall portion of the water jacket of the cylinder block, and the guide portion is arranged to be close to the outer wall portion of the water jacket of the cylinder block. It is a rib formed to protrude outward from the wall surface,
The cooling structure for a multi-cylinder engine according to claim 2.

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