JP6708172B2 - Intercooler - Google Patents

Description

The present invention relates to an intercooler that cools supercharged intake air pressurized by a supercharger.

2. Description of the Related Art Conventionally, an intercooler is known that cools supercharged intake air by exchanging heat between supercharged air that is supercharged in an engine by a supercharger and two types of cooling water having different temperatures (for example, patents). Reference 1). The intercooler described in Patent Document 1 has a high-temperature cooling water flow path through which high-temperature cooling water flows upstream in the flow direction of supercharged intake air, and a low-temperature cooling water flow through which low-temperature cooling water flows downstream in the flow direction of supercharged intake air. A cooling water flow path is arranged. Further, fins for accelerating heat exchange between the cooling water and the supercharged intake air are arranged in the high temperature cooling water passage and the low temperature cooling water passage.

According to this, the low-temperature cooling water can be warmed up early by the heat of the high-temperature cooling water when the engine is started. Further, since the supercharged intake air can be pre-cooled with the high temperature cooling water before being cooled with the low temperature cooling water, the cooling performance of the supercharged intake air cooling system can be improved.

JP, 2005-155692, A

In the intercooler described in Patent Document 1, the cooling water and the high-temperature supercharged intake air exchange heat in the high-temperature cooling water flow path, so that the temperature of the cooling water may rise to around the boiling point. Particularly in the case of a configuration in which the cooling water passage is narrowed, the water resistance increases, the water pressure near the outlet of the cooling water passage decreases, and the boiling point of the cooling water decreases. For this reason, boiling of the cooling water is a concern in the high-temperature cooling water passage where the temperature of the cooling water tends to rise.

When the cooling water boils, foreign substances derived from the components contained in the cooling water are generated, and these foreign substances may accumulate in the water flow path, leading to a problem that the flow path is blocked. Further, in the case where the cooling water flow passage is narrowed, the flow passage is easily blocked due to the accumulation of foreign matter.

In view of the above points, an object of the present invention is to suppress the flow path clogging due to the accumulation of foreign matter in an intercooler that cools supercharged intake air with two types of cooling media having different temperatures.

In order to achieve the above object, in the invention described in claim 1, the supercharged intake air is cooled by exchanging heat between the supercharged intake air supercharged in the engine (10) by the supercharger and the cooling medium. Which is an intercooler that includes a heat exchange section (200) for exchanging heat between the cooling medium flowing inside the flow channel pipe (201) and the supercharged intake air flowing outside the flow channel pipe. A first cooling medium and a second cooling medium having a temperature higher than that of the first cooling medium are included, and the first cooling medium flows in the flow path pipe so as to intersect the flow direction of the supercharged intake air. A cooling medium flow channel (204) and a second cooling medium flow channel (205) through which the second cooling medium flows so as to intersect the flow direction of the supercharged intake air are formed, and the second cooling medium flow channel is The second cooling medium flow passage is arranged upstream of the first cooling medium flow passage in the flow direction of the supercharged intake air, and the fin (207) is provided inside the first cooling medium flow passage. No fins are provided inside the second cooling medium flow path, and the second cooling medium flow path has a second cooling medium U-turn portion (205d) for making a U-turn of the second cooling medium. A column portion (206) that joins the opposing inner surfaces with each other while keeping a predetermined gap, and a portion (205e, where the flow direction of the second cooling medium and the flow direction of the supercharged intake air intersect). It is characterized in that a projection (205g) is formed on the inner surface of 205f) .

As a result, in the first cooling medium flow path in which the fins are arranged, the heat transfer area is enlarged, and the effect of promoting heat exchange between the first cooling medium and the supercharged intake air can be obtained. On the other hand, in the second cooling medium flow path in which the fins are not arranged, the water resistance can be reduced and the boiling point of the second cooling medium can be raised. As a result, the second cooling medium flowing through the second cooling medium flow path is less likely to boil, and the generation of foreign matter due to the boiling of the second cooling medium can be suppressed.

Further, since the fins are not provided in the second cooling medium passage, the passage of the second cooling medium is wide. Therefore, even if foreign matter is generated in the second cooling medium, it is possible to prevent foreign matter from accumulating in the flow path, and it is possible to avoid blocking the flow path with foreign matter as much as possible.
Further, in the invention according to claim 2, the second cooling medium flow path has a second cooling medium U-turn portion (205d) for making a U-turn of the second cooling medium, and in the second cooling medium U-turn portion, Columns (206) are formed to join the opposing inner surfaces with each other while maintaining a predetermined gap, and the portions (205e, 205f) where the flow direction of the second cooling medium and the flow direction of supercharged intake air intersect. Is characterized in that a protrusion (205g) is formed on the inner surface thereof.

Note that the reference numerals in parentheses of the above-mentioned means indicate the correspondence with the specific means described in the embodiments described later.

It is a block diagram which shows the outline of the supercharged intake air cooling system of the vehicle in 1st Embodiment. It is a top view of the intercooler in a 1st embodiment. It is a perspective view of the intercooler in a 1st embodiment. It is a perspective view showing the important section of the intercooler in a 1st embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 1st Embodiment. It is a perspective view which shows the fin in 1st Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 2nd Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 3rd Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 4th Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 5th Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 6th Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 7th Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 8th Embodiment. It is a schematic diagram which shows the inside of the flow path pipe in 9th Embodiment. It is a perspective view which shows the fin of a modification.

Embodiments of the present invention will be described below with reference to the drawings. In the following respective embodiments, the same or equivalent portions are designated by the same reference numerals in the drawings.

(First embodiment)
A first embodiment of the present invention will be described with reference to the drawings. The first embodiment will describe an example in which the intercooler of the present invention is applied to a supercharged intake air cooling system for a vehicle.

As shown in FIG. 1, an intake system of a vehicle engine (internal combustion engine) 10 is provided with a supercharger (not shown) for supercharging intake air to the engine 10. This supercharger is provided to supplement the maximum output of the engine 10. That is, in the vehicle according to the present embodiment, the engine 10 has a small displacement for the purpose of improving fuel consumption, and the decrease in the maximum output due to the reduction in the displacement is compensated by the supercharger.

In the intake system, an intercooler 20 that cools engine intake air is provided downstream of the supercharger in the intake flow. The intercooler 20 serves to cool the supercharged intake air compressed by the supercharger and improve the charging efficiency of the engine intake air. The intercooler 20 of the present embodiment is a two-temperature water-cooled intercooler that cools the supercharged intake air by two independent cooling water systems having different temperatures.

The intercooler 20 is provided in a low temperature cooling water circuit 30 in which low temperature cooling water circulates, and the low temperature cooling water flows through the inside of the intercooler 20. Further, inside the intercooler 20, high temperature cooling water circulating in the high temperature cooling water circuit 40 also flows. The intercooler 20 cools the supercharged intake air by exchanging heat between the supercharged intake air compressed by the supercharger and the low temperature cooling water and the high temperature cooling water. LLC (antifreeze liquid), water, etc. can be used as low-temperature cooling water and high-temperature cooling water.

The low-temperature cooling water circuit 30 is provided with a water pump 31 for circulating the low-temperature cooling water. In the low-temperature cooling water circuit 30, the heat of the low-temperature cooling water is radiated to the outside air between the water pump 31 and the intercooler 20. A first radiator (first radiator) 32 that cools the cooling water is provided.

The high-temperature cooling water circuit 40 is provided with a water pump 41, a second radiator (second radiator) 42, and a heater core (heating heat exchanger) 43. The water pump 41 circulates the high temperature cooling water in the high temperature cooling water circuit 40. The second radiator 42 radiates the heat absorbed by the high-temperature cooling water from the engine 10 to the outside air. The heater core 43 heats the blown air by exchanging heat between the blown air blown into the vehicle interior and the high temperature cooling water. The intercooler 20, the second radiator 42, and the heater core 43 are arranged in parallel in the high temperature cooling water circuit 40.

Since the high temperature cooling water is absorbing heat from the engine 10, the temperature of the high temperature cooling water becomes higher than the temperature of the low temperature cooling water when flowing through the inside of the intercooler 20. The low temperature cooling water of the present embodiment corresponds to the first cooling medium of the present invention, and the high temperature cooling water of the present embodiment corresponds to the second cooling medium of the present invention.

Subsequently, the intercooler 20 of the first embodiment will be described in detail. As shown in FIGS. 2 and 3, the intercooler 20 includes a duct 21, a flange 22, a tank 23, a cooling water pipe 24, and a heat exchange section 200. The heat exchange section 200 is provided inside the duct 21 and exchanges heat between the supercharged intake air and the cooling water.

The duct 21 is a tubular part through which the supercharged intake air flows, and is provided with an inflow port through which the supercharged intake air flows in and an outflow port through which the supercharged intake air flows out. A flange 22 is provided at each of the inlet and the outlet of the duct 21. A tank 23 is fixed to the inlet and outlet of the duct 21 by a flange 22. The flange 22 and the tank 23 can be fixed to each other by caulking.

The tank 23 is a tubular member through which supercharged intake air flows. The supercharged intake air flowing through the tank 23 connected to the inlet of the duct 21 flows into the inlet of the duct 21, and the supercharged intake air flowing out of the outlet of the duct 21 flows into the tank 23 connected to the outlet of the duct 21. Flowing.

The duct 21 is provided with a cooling water pipe 24 to which a pipe (not shown) through which cooling water flows is connected. The intercooler 20 is connected to the radiators 32 and 42, the heater core 43, and the like via the pipes. The cooling water pipe 24 includes a low temperature side inflow pipe 24 a for injecting the low temperature cooling water into the heat exchange unit 200, a low temperature side outflow pipe 24 b for outflowing the low temperature cooling water from the heat exchange unit 200, and a high temperature cooling water inflow into the heat exchange unit 200. It includes a high temperature side inflow pipe 24c and a high temperature side outflow pipe 24d for outflowing the high temperature cooling water from the heat exchange section 200.

The heat exchange section 200 of the intercooler 20 of the present embodiment is configured as a so-called drone cup type heat exchanger. As shown in FIG. 4, in the heat exchange section 200, a plurality of flow channel pipes 201 and fins 202 joined between adjacent flow channel pipes 201 are alternately stacked. The flow path tube 201 is formed by joining a pair of opposing plate-shaped members 203 in the middle. The flow channel tube 201 has a flat cross section.

All or some of the components of the heat exchange section 200 are made of a clad material in which a brazing material is clad on the surface of a core material made of, for example, aluminum. By heating the surface of the clad material with the flux applied, the components of the heat exchange section 200 are brazed and joined.

The heat exchange section 200 is configured to exchange heat between the cooling water flowing inside the flow path pipe 201 and the supercharged intake air flowing outside the flow path pipe 201. The space in which the fins 202 are arranged between the laminated flow passage pipes 201 and the flow passage pipes 201 constitutes a supercharged intake flow passage through which the supercharged intake air flows.

The fins 202 are corrugated fins formed by bending a thin plate material in a wave shape, are joined to the flat outer surface side of the flow path pipe 201, and promote heat exchange for expanding the heat transfer area between supercharged intake air and cooling water. Make up the department.

As shown in FIG. 5, a low temperature cooling water flow path 204 through which low temperature cooling water flows and a high temperature cooling water flow path 205 through which high temperature cooling water flows are formed in the flow path pipe 201. The flow direction of the cooling water in these cooling water flow paths 204 and 205 is a direction intersecting the flow direction of the supercharged intake air, specifically, a direction orthogonal to the flow direction of the supercharged intake air. The flow direction of the supercharged intake air in FIG. 5 is from the lower side to the upper side. The low-temperature cooling water passage 204 corresponds to the first cooling medium passage of the present invention, and the high temperature cooling water passage 205 corresponds to the second cooling medium passage of the present invention.

The low-temperature cooling water passage 204 and the high-temperature cooling water passage 205 are arranged in parallel in the passage pipe 201, and are arranged on the upstream side and the downstream side in the flow direction of the supercharged intake air. Specifically, the high temperature cooling water passage 205 is arranged on the upstream side in the supercharging intake air flow direction, and the low temperature cooling water passage 204 is arranged on the downstream side in the supercharging intake air flow direction. That is, in the present embodiment, the high temperature cooling water flows in the upstream side of the supercharging intake passage through which the supercharging intake air passes, and the low temperature cooling water flows in the downstream side of the supercharging intake passage.

As shown in FIG. 5, the flow path pipe 201 includes a low temperature side inlet portion 204a for allowing the low temperature cooling water to flow into the low temperature cooling water passage 204, a low temperature side outlet portion 204b for allowing the low temperature cooling water to flow out from the low temperature cooling water passage 204, and a high temperature. A high temperature side inlet portion 205a that allows the high temperature cooling water to flow into the cooling water passage 205 and a high temperature side outlet portion 205b that causes the high temperature cooling water to flow out from the high temperature cooling water passage 205 are provided. The low temperature side inlet portion 204a, the low temperature side outlet portion 204b, the high temperature side inlet portion 205a and the high temperature side outlet portion 205b are formed by forming through holes in the flow path pipe 201.

The low-temperature cooling water flow path 204 is provided with a low-temperature side partition part 204c for partitioning the flow path and a low-temperature side U-turn part 204d for making a U-turn of the low-temperature cooling water. The low-temperature cooling water flow path 204 includes a first low-temperature side flow path section 204e located upstream of the low-temperature side U-turn section 204d and a second low-temperature side U-turn section 204d located downstream of the low-temperature side U-turn section 204d by the low-temperature side partition section 204c. It is partitioned into the low temperature side flow passage portion 204f. The low temperature side U-turn portion 204d corresponds to the first cooling medium U-turn portion of the present invention.

The flow direction of the low temperature cooling water flowing through the low temperature cooling water passage 204 is changed at the low temperature side U-turn portion 204d. For this reason, the flow directions of the low-temperature cooling water are opposite in the first low temperature side flow passage portion 204e and the second low temperature side flow passage portion 204f.

In the low temperature cooling water flow path 204, the first low temperature side flow path portion 204e and the second low temperature side flow path portion 204f are portions where the flow direction of the low temperature cooling water and the flow direction of the supercharged intake air intersect. In the present embodiment, in the first low temperature side flow passage portion 204e and the second low temperature side flow passage portion 204f, the flow direction of the low temperature cooling water and the flow direction of the supercharged intake air are orthogonal to each other.

The high temperature cooling water passage 205 is provided with a high temperature side partition portion 205c for partitioning the passage and a high temperature side U-turn portion 205d for making a U turn of the high temperature cooling water. The high temperature cooling water flow path 205 includes a first high temperature side flow path section 205e located upstream of the high temperature side U turn section 205c and a second high temperature side U turn section 205c located downstream of the high temperature side U turn section 205c by the high temperature side partition section 205c. It is partitioned by the high temperature side flow passage portion 205f. The high temperature side U-turn portion 205d corresponds to the second cooling medium U-turn portion of the present invention.

The high temperature cooling water flowing through the high temperature cooling water passage 205 changes its flow direction at the high temperature side U-turn portion 205d. Therefore, in the high-temperature cooling water flow path 205, the flow directions of the high-temperature cooling water are opposite in the first high-temperature side flow path portion 205e and the second high-temperature side flow path portion 205f.

In the high temperature cooling water passage 205, the first high temperature side passage portion 205e and the second high temperature side passage portion 205f are portions where the flow direction of the high temperature cooling water and the flow direction of the supercharged intake air intersect. In the present embodiment, in the first high temperature side flow passage portion 205e and the second high temperature side flow passage portion 205f, the flow direction of the high temperature cooling water and the flow direction of the supercharged intake air are orthogonal to each other.

In the present embodiment, the low temperature side inlet portion 204a, the low temperature side outlet portion 204b, the high temperature side inlet portion 205a and the high temperature side outlet portion 205b are disposed at one end portion in the longitudinal direction of the flow path pipe 201 (that is, the left end of FIG. 5). Section). These are arranged in the order of the high temperature side outlet portion 205b, the high temperature side inlet portion 205a, the low temperature side outlet portion 204b, and the low temperature side inlet portion 204a from the upstream side in the flow direction of the supercharged intake air. Further, the low temperature side U-turn portion 204d and the high temperature side U-turn portion 205d are arranged at the other end portion (that is, the right end portion in FIG. 5) in the longitudinal direction of the flow path pipe 201.

In the present embodiment, the length D _HT in the supercharging intake air flow direction in the portion of the flow path pipe 201 where the high temperature cooling water flow path 205 is formed is such that the low temperature cooling water flow path 204 of the flow path pipe 201 is formed. It is shorter than the length D _LT in the flow direction of the supercharged intake air in the existing portion. In the present embodiment, the length D _LT of the low temperature cooling water flow path 204 in the supercharged intake flow direction is determined by the supercharged intake air of the first low temperature side flow path section 204e, the second low temperature side flow path section 204f and the low temperature side partition section 204c. It is almost equal to the sum of the lengths in the flow direction. In the present embodiment, the length D _HT of the high temperature cooling water flow path 205 in the flow direction of the supercharged intake air is equal to the supercharged intake air of the first high temperature side flow path portion 205e, the second high temperature side flow path portion 205f and the high temperature side partition portion 205c. It is almost equal to the sum of the lengths in the flow direction.

A column portion 206 is provided on the low temperature side U-turn portion 204d of the low temperature cooling water channel 204 and the high temperature side U turn portion 205d of the high temperature cooling water channel 205. The column portion 206 is formed on each of the pair of plate-shaped members 203 forming the flow channel tube 201 so as to project into the flow channel. The pillar portions 206 formed at the corresponding positions of the pair of plate-shaped members 203 are joined together. The pair of plate-shaped members 203 are joined to each other in a state in which a predetermined interval is maintained by the column portion 206. That is, the inner surfaces of the flow path pipe 201, which face each other, are joined to each other by the pillar portions 206. The braces 206 can improve the brazing property of the pair of plate-shaped members 203 that form the flow path tube 201, and further improve the strength of the flow path tube 201.

Inside the low-temperature cooling water channel 204, fins 207 that divide the low-temperature cooling water channel 204 into a plurality of fine channels are arranged. The fins 207 provided in the low-temperature cooling water flow path 204 constitute a heat exchange promotion unit for increasing the heat transfer area between the low-temperature cooling water and the supercharged intake air. The fins 207 are arranged in the first low temperature side flow passage portion 204e and the second low temperature side flow passage portion 204f of the low temperature cooling water flow passage 204, respectively.

As shown in FIG. 6, the fin 207 of this embodiment is configured as a straight fin. The fin 207 having a straight fin structure has a corrugated shape in which the wall portion 207a and the top portion 207b are continuous, and a corrugated cross-sectional shape is formed in the direction in which the waves continue. The plurality of wall portions 207a and the plurality of top portions 207b are provided in parallel, respectively. The plurality of wall portions 207a and the plurality of top portions 207b each extend linearly along the flow direction of the low temperature cooling water.

Returning to FIG. 5, no fins are arranged inside the high temperature cooling water passage 205. Therefore, the high temperature cooling water flow path 205 is not divided into a plurality of fine flow paths by the fins.

Further, in the high temperature cooling water flow passage 205, the inner surface of the flow passage is formed flat in the first high temperature side flow passage portion 205e and the second high temperature side flow passage portion 205f. That is, in the high-temperature cooling water flow path 205, no protrusions or irregularities are formed on the inner surface of the portion excluding the high-temperature side U-turn portion 205d.

According to the present embodiment described above, in the intercooler 20 that cools the supercharged intake air with the two types of cooling water having different temperatures, the fins 207 are provided inside the low-temperature cooling water flow passage 204 and the high-temperature cooling water flow passage 205 is provided. There are no fins inside. Therefore, in the low-temperature cooling water flow path 204 in which the fins 207 are arranged, the heat transfer area is expanded, and the effect of promoting heat exchange between the low-temperature cooling water and the supercharged intake air can be obtained.

On the other hand, in the high-temperature cooling water flow path 205 in which the fins are not arranged, the water resistance can be reduced and the boiling point of the high-temperature cooling water can be raised. This makes it difficult for the high-temperature cooling water flowing through the high-temperature cooling water channel 205 to boil, and suppresses the generation of foreign matter due to the boiling of the high-temperature cooling water.

Further, since the high-temperature cooling water flow path 205 is not provided with fins, the high-temperature cooling water flow path is wider than in the case where the fins are provided. Therefore, even if foreign matter is generated in the high-temperature cooling water, it is possible to prevent foreign matter from accumulating in the high-temperature cooling water channel 205, and to prevent the channel from being blocked by the foreign matter as much as possible.

Further, in the present embodiment, the inner surfaces of the high temperature side flow passage portions 205e and 205f of the high temperature cooling water flow passage 205 are flat. Therefore, even if a foreign substance occurs in the high-temperature cooling water, it is possible to prevent the foreign substance from accumulating in the flow channel, and it is possible to avoid blocking the flow channel by the foreign substance as much as possible.

Further, in the present embodiment, the length D _HT of the high temperature cooling water flow path 205 in the supercharging intake air flow direction is shorter than the length D _{LT of the} low temperature cooling water flow path 204 in the supercharging intake air flow direction, The flow passage cross-sectional area of the cooling water flow passage 205 is smaller than the flow passage cross-sectional area of the low temperature cooling water flow passage 204. Therefore, the flow rate of the cooling water becomes higher in the high temperature cooling water flow path 205 than in the low temperature cooling water flow path 204, and the water side heat transfer coefficient with respect to the water side heat transfer area is increased in the heat exchange of the supercharged intake air and the high temperature cooling water. Can be improved. As a result, in the high temperature cooling water flow path 205, it is possible to suppress the deterioration of the heat exchange performance due to the absence of fins.

Further, in the present embodiment, since the pillar portion 206 is formed in the low temperature cooling water flow path 204 and the high temperature cooling water flow path 205, brazing property can be improved and the strength of the flow path pipe 201 can be improved. You can Further, the U-turn portions 204d and 205d form a relatively large space in the cooling water flow paths 204 and 205, and the amount of deformation tends to increase when thermal stress occurs in the flow path pipe 201. By providing the column portion 206 on the U-turn portions 204d and 205d, the strength of the U-turn portions 204d and 205d can be secured.

(Second embodiment)
Next, a second embodiment of the present invention will be described based on FIG. In the second embodiment, only parts different from the first embodiment will be described. The second embodiment is different from the first embodiment in the configuration of the low-temperature cooling water passage 204.

As shown in FIG. 7, in the second embodiment, the low temperature cooling water passage 204 is not provided with the low temperature side partition portion 204c and the low temperature side U-turn portion 204d. Further, in the low temperature cooling water channel 204, the low temperature side inlet portion 204a and the low temperature side outlet portion 204b are arranged at different ends in the longitudinal direction of the flow channel pipe 201. The low temperature side inlet portion 204a is arranged at one end portion (that is, the left end portion in FIG. 7) in the longitudinal direction of the flow channel tube 201, and the low temperature side outlet portion 204b is in the longitudinal direction of the flow channel tube 201. It is arranged at the other end (that is, the right end in FIG. 7).

Therefore, in the low temperature cooling water flow path 204 of the second embodiment, the low temperature cooling water flows in one direction. In the example shown in FIG. 7, in the low temperature cooling water flow path 204, the low temperature cooling water flows in the direction from the left side to the right side in the drawing.

The high temperature cooling water flow path 205 has the same configuration as that of the first embodiment, and is provided with a high temperature side partition portion 205c and a high temperature side U-turn portion 205d. Therefore, in the high temperature cooling water flow path 205, the high temperature cooling water makes a U-turn and flows.

In the second embodiment described above, the low-temperature cooling water flow path 204 is configured so that the low-temperature cooling water flows in one direction, and the high-temperature cooling water flow path 202 causes the high-temperature cooling water to make a U-turn. Even with such a configuration, the same effect as that of the first embodiment can be obtained.

(Third Embodiment)
Next, a third embodiment of the present invention will be described based on FIG. In the third embodiment, only parts different from the above embodiments will be described. The third embodiment is different from the first embodiment in the configuration of the high temperature cooling water passage 205.

As shown in FIG. 8, in the third embodiment, the high temperature cooling water passage 205 is not provided with the high temperature side partition portion 205c and the high temperature side U-turn portion 205d. Further, in the high temperature cooling water channel 205, the high temperature side inlet portion 205a and the high temperature side outlet portion 205b are arranged at different ends in the longitudinal direction of the flow channel pipe 201. The high temperature side inlet portion 205a is arranged at one end portion (that is, the left end portion in FIG. 8) in the longitudinal direction of the flow channel pipe 201, and the high temperature side outlet portion 205b is in the longitudinal direction of the flow channel pipe 201. It is arranged at the other end (that is, the right end in FIG. 8).

Therefore, in the high temperature cooling water flow path 205 of the third embodiment, the high temperature cooling water flows in one direction. In the example shown in FIG. 8, in the high temperature cooling water passage 205, the high temperature cooling water flows in the direction from the left side to the right side in the drawing.

The low temperature cooling water flow path 204 has the same configuration as that of the first embodiment, and is provided with a low temperature side partition section 204c and a low temperature side U-turn section 204d. Therefore, in the low temperature cooling water flow path 204, the low temperature cooling water flows in a U-turn.

In the third embodiment described above, the low-temperature cooling water flow path 204 is configured such that the low-temperature cooling water makes a U-turn and flows, and the high-temperature cooling water flow path 202 flows in one direction. Even with such a configuration, the same effect as that of the first embodiment can be obtained.

Further, in the third embodiment, since the high temperature cooling water is configured to flow in one direction in the high temperature cooling water passage 202, the high temperature cooling water as in the first and second embodiments makes a U-turn. The flow passage cross-sectional area of the high-temperature cooling water can be increased as compared with the configuration in which the high-temperature cooling water flows. Therefore, even if a foreign substance occurs in the high-temperature cooling water, it is possible to prevent the foreign substance from accumulating in the flow channel, and it is possible to avoid blocking the flow channel by the foreign substance as much as possible.

(Fourth Embodiment)
Next, a fourth embodiment of the present invention will be described based on FIG. In the fourth embodiment, only parts different from the above embodiments will be described. The fourth embodiment differs from the first embodiment in the configurations of the low-temperature cooling water passage 204 and the high-temperature cooling water passage 205.

As shown in FIG. 9, in the fourth embodiment, the low temperature cooling water passage 204 is provided with two low temperature side partition parts 204c and 204g and two low temperature side U-turn parts 204d and 204h. The low temperature cooling water flow path 204 is divided into three flow paths 204e, 204f, 204i by two low temperature side partition parts 204c, 204g.

The low-temperature cooling water flow path 204 includes a first low-temperature side partition section 204c, a first low-temperature side flow path section 204e located upstream of the first low-temperature side U turn section 204d, and a first low-temperature side U-turn section 204d. It is partitioned by the second low temperature side flow passage portion 204f located on the side. In addition, the low-temperature cooling water flow path 204 includes a second low-temperature side partition section 204g, a second low-temperature side flow path section 204f located upstream of the second low-temperature side U-turn section 204h, and a second low-temperature side U-turn section 204h. It is partitioned into a third low temperature side flow passage portion 204i located on the further downstream side.

The low-temperature cooling water flowing through the low-temperature cooling water passage 204 changes its flow direction twice by the two low-temperature side U-turn parts 204d and 204h. Therefore, in the low-temperature cooling water flow path 204, the flow directions of the low-temperature cooling water are opposite in the first low-temperature side flow path section 204e and the second low-temperature side flow path section 204f, and the second low-temperature side flow path section 204f And the flow direction of the low-temperature cooling water is opposite in the third low-temperature side flow path portion 204i.

Further, in the low temperature cooling water channel 204, the low temperature side inlet portion 204a and the low temperature side outlet portion 204b are arranged at different ends in the longitudinal direction of the flow channel pipe 201. The low temperature side inlet portion 204a is arranged at one end portion (that is, the left end portion in FIG. 9) in the longitudinal direction of the flow channel tube 201, and the low temperature side outlet portion 204b is in the longitudinal direction of the flow channel tube 201. It is arranged at the other end (that is, the right end in FIG. 9).

The high temperature cooling water flow path 205 has the same configuration as that of the third embodiment, and is not provided with the high temperature side partition portion 205c and the high temperature side U-turn portion 205d. Therefore, in the high temperature cooling water passage 205, the high temperature cooling water flows in one direction.

In the fourth embodiment described above, the low-temperature cooling water flow path 204 is configured such that the low-temperature cooling water makes a U-turn twice and the high-temperature cooling water flow path 202 causes the high-temperature cooling water to flow in one direction. Even with such a configuration, the same effect as that of the first and third embodiments can be obtained.

(Fifth Embodiment)
Next, a fifth embodiment of the present invention will be described based on FIG. In the fifth embodiment, only parts different from the above embodiments will be described. The fifth embodiment is different from the first embodiment in the configurations of the low-temperature cooling water passage 204 and the high-temperature cooling water passage 205.

As shown in FIG. 10, in the fifth embodiment, the low temperature cooling water passage 204 is provided with three low temperature side partition parts 204c, 204g, 204j and three low temperature side U-turn parts 204d, 204h, 204k. .. The low temperature cooling water flow path 204 is divided into four flow paths 204e, 204f, 204i and 204l by three low temperature side partition parts 204c, 204g and 204j.

The low-temperature cooling water flow path 204 includes a first low-temperature side partition section 204c, a first low-temperature side flow path section 204e located upstream of the first low-temperature side U turn section 204d, and a first low-temperature side U-turn section 204d. It is partitioned by the second low temperature side flow passage portion 204f located on the side. In addition, the low-temperature cooling water flow path 204 includes a second low-temperature side partition section 204g, a second low-temperature side flow path section 204f located upstream of the second low-temperature side U-turn section 204h, and a second low-temperature side U-turn section 204h. It is partitioned into a third low temperature side flow passage portion 204i located on the further downstream side. In addition, the low-temperature cooling water flow path 204 includes a third low-temperature side partition part 204j, a third low-temperature side flow path part 204i located upstream of the third low-temperature side U-turn part 204k, and a third low-temperature side U-turn part 204k. It is partitioned into a fourth low temperature side flow passage portion 204l located on the further downstream side.

The low-temperature cooling water flowing through the low-temperature cooling water passage 204 changes its flow direction three times by the three low-temperature side U-turn parts 204d, 204h, and 204k. Therefore, in the low-temperature cooling water flow path 204, the flow directions of the low-temperature cooling water are opposite in the first low-temperature side flow path section 204e and the second low-temperature side flow path section 204f, and the second low-temperature side flow path section 204f And the flow directions of the low temperature cooling water in the third low temperature side flow passage portion 204i are opposite to each other, and the flow directions of the low temperature cooling water in the third low temperature side flow passage portion 204i and the fourth low temperature side flow passage portion 204l are opposite to each other. It is in the direction.

Further, in the low temperature cooling water flow path 204, the low temperature side inlet portion 204a and the low temperature side outlet portion 204b are arranged at one end portion in the longitudinal direction of the flow passage pipe 201 (that is, the left end portion in FIG. 10).

The high temperature cooling water flow path 205 has the same configuration as that of the third embodiment, and is not provided with the high temperature side partition portion 205c and the high temperature side U-turn portion 205d. Therefore, in the high temperature cooling water passage 205, the high temperature cooling water flows in one direction.

In the fifth embodiment described above, the low-temperature cooling water passage 204 is configured so that the low-temperature cooling water makes three U-turns, and the high-temperature cooling water passage 202 allows the high-temperature cooling water to flow in one direction. Even with such a configuration, the same effect as that of the first and third embodiments can be obtained.

(Sixth Embodiment)
Next, a sixth embodiment of the present invention will be described based on FIG. In the sixth embodiment, only parts different from the above embodiments will be described. The sixth embodiment is different from the first embodiment in the configurations of the low-temperature cooling water passage 204 and the high-temperature cooling water passage 205.

As shown in FIG. 11, in the sixth embodiment, the low-temperature cooling water flow path 204 has the same configuration as in the second embodiment, and the low-temperature cooling water flow path 204 has a low-temperature side partition part 204c and a low-temperature side U-turn. The part 204d is not provided. Therefore, in the low temperature cooling water flow path 204 of the sixth embodiment, the low temperature cooling water flows in one direction.

Further, the high temperature cooling water passage 205 has the same configuration as that of the third embodiment, and the high temperature cooling water passage 205 is not provided with the high temperature side partition portion 205c and the high temperature side U-turn portion 205d. Therefore, in the high temperature cooling water passage 205 of the sixth embodiment, the high temperature cooling water flows in one direction.

In the sixth embodiment described above, the low temperature cooling water passage 204 is configured so that the low temperature cooling water flows in one direction and the high temperature cooling water passage 202 allows the high temperature cooling water to flow in one direction. Even with such a configuration, the same effect as that of the first and third embodiments can be obtained.

(Seventh embodiment)
Next, a seventh embodiment of the present invention will be described based on FIG. In the seventh embodiment, only parts different from the above embodiments will be described. The seventh embodiment is different from the first embodiment in the configuration of the high temperature cooling water passage 205.

As shown in FIG. 12, in the seventh embodiment, similar to the first embodiment, the low-temperature cooling water passage 204 and the high-temperature cooling water passage 205 both make U-turns of the cooling water. In addition, in the seventh embodiment, the column part 206 is not provided on the high temperature side U-turn part 205 d of the high temperature cooling water flow path 205. Therefore, in the high temperature cooling water flow path 205, in addition to the high temperature side flow path parts 205e and 205f, the inner surface of the high temperature side U-turn part 205d is formed flat. That is, in the high temperature cooling water channel 205 of the seventh embodiment, the inner surface is formed flat over the entire channel.

In the seventh embodiment described above, the high-temperature cooling water channel 205 is formed so that the inner surface of the entire channel is flat. Even with such a configuration, the same effect as that of the first embodiment can be obtained.

In addition, in the seventh embodiment, in addition to the high temperature side flow path portions 205e and 205f, the inner surface of the high temperature side U-turn portion 205d is formed flat. Therefore, even if foreign matter occurs in the high-temperature cooling water, it is possible to prevent foreign matter from accumulating in the flow path even in the high temperature side U-turn portion 205d, and it is possible to prevent the flow path from being blocked by the foreign matter as much as possible. Become.

(Eighth Embodiment)
Next, an eighth embodiment of the present invention will be described based on FIG. In the eighth embodiment, only parts different from the above embodiments will be described. The eighth embodiment is different from the first embodiment in the configuration of the high temperature cooling water passage 205.

As shown in FIG. 13, in the eighth embodiment, in the high temperature cooling water flow passage 205, the protrusion 205g is formed so as to protrude toward the flow passage. In FIG. 13, the protrusion 205g is indicated by a black circle.

The protrusion portion 205g is formed on the inner surfaces of the first high temperature side flow passage portion 205e, the second high temperature side flow passage portion 205f, and the high temperature side U-turn portion 205d. That is, in the high temperature cooling water channel 205 of the eighth embodiment, the protrusion 205g is formed on the inner surface over the entire channel. The protrusion 205g constitutes a turbulent flow generation unit that generates a turbulent flow in the high temperature cooling water flowing through the high temperature cooling water passage 205.

In the eighth embodiment described above, the protrusion 205g is provided over the entire high temperature cooling water flow path 205. Even with such a configuration, the same effect as that of the first embodiment can be obtained.

In addition, since the high temperature cooling water flow path 205 is provided with the protrusion 205g, the heat transfer efficiency between the high temperature cooling water and the supercharged intake air can be improved. For this reason, in the high temperature cooling water flow path 205, it is possible to suppress deterioration of the heat exchange performance due to the absence of fins.

(9th Embodiment)
Next, a ninth embodiment of the present invention will be described based on FIG. In the ninth embodiment, only parts different from the above embodiments will be described. The ninth embodiment is different from the first embodiment in the configuration of the high temperature cooling water passage 205.

As shown in FIG. 14, in the ninth embodiment, in the high temperature cooling water flow passage 205, protrusions are formed on the high temperature side flow passage portions 205e and 205f, which are portions where the flow direction of the high temperature cooling water and the flow direction of the supercharged intake air intersect. The portion 205g is formed. Further, in the high temperature cooling water flow path 205, a pillar portion 206 is provided on the high temperature side U-turn portion 205d.

In the ninth embodiment described above, in the high temperature cooling water flow passage 205, the high temperature side flow passage portions 205e and 205f are provided with the protrusions 205g, and the high temperature side U-turn portion 205d is provided with the column portion 206. Even with such a configuration, the same effect as that of the first embodiment can be obtained.

Further, since the high temperature side flow passage portions 205e and 205f are provided with the protrusions 205g, the heat transfer efficiency between the high temperature cooling water and the supercharged intake air can be improved, and the high temperature side U-turn portion 205d is provided with the support columns. By providing 206, the strength of the U-turn portion 205d on the high temperature side can be secured.

(Other embodiments)
The present invention is not limited to the above-described embodiments, but can be variously modified as follows without departing from the spirit of the present invention. Further, the means disclosed in each of the above embodiments may be appropriately combined within a practicable range.

(1) In each of the above-described embodiments, the duct 21 of the intercooler 20 is connected to the tank 23 through which supercharged intake air flows, and the heat exchange section 200 is provided inside the duct 21 (see FIGS. 2 and 3). However, the configuration is not limited to this, and the intercooler 20 may have a different configuration. For example, the intercooler 20 may be inserted into the intake manifold. In this case, the duct 21 forming the flow path of the supercharged intake air is not necessary, and a plate for fixing to the wall surface of the intake manifold is provided in the intercooler, and the heat exchange section 200 may be fixed to this plate.

(2) In each of the above-described embodiments, the heat exchange section 200 of the intercooler 20 has a laminated structure in which fins 202 that are joined between the flow passage pipes 201 and the adjacent flow passage pipes 201 are alternately laminated (see FIG. 4). However, the present invention is not limited to this and may have a different configuration. For example, the heat exchange unit 200 of the intercooler 20 may be a core plate type in which the ends of the tubes are inserted into a pair of core plates. In this case, the supercharged intake air may pass inside the tube and the cooling water may pass outside the tube, or the cooling water may pass inside the tube and the supercharged intake air may pass outside the tube. You can

(3) In the first embodiment, the column 206 is provided only on the U-turn portion 205d of the high temperature cooling water channel 205, but the present invention is not limited to this. The high temperature side channel portion 205e of the high temperature cooling water channel 205 is not limited to this. 205f may be provided with the column portion 206.

(4) In each of the above embodiments, the fins 207 arranged in the low-temperature cooling water flow path 204 are configured as straight fins (see FIG. 6), but the present invention is not limited to this, and the fins 207 may have different shapes.

For example, as shown in FIG. 15, the fin 207 may be configured as an offset fin. The fin 207 configured as an offset fin has a corrugated cross section in which a wall portion 207a and a top portion 207b are continuous, and the wall portion 207a is provided with a large number of cut and raised portions 207c that are partially cut and raised. .. The wall portions 207a and the cut-and-raised portions 207c are alternately arranged in a zigzag pattern along the flow direction of the low-temperature cooling water.

Further, the fin 207 may be configured as a wave fin (not shown). The wave fin has a wave-shaped cross section in which the wall portion 207a and the top portion 207b are continuous, and the wall portion 207a and the top portion 207b are formed so as to meander along the flowing direction of the low-temperature cooling water.

(5) In each of the above-described embodiments, the fins are not provided inside the high temperature cooling water passage 205 at all, but it is excluded that there are relatively small fins inside the high temperature cooling water passage 205. is not. That is, fins may be provided in the high-temperature cooling water flow passage 205 as long as the flow passage can be suppressed from being blocked by foreign matter in the high-temperature cooling water.

10 engine 20 intercooler 200 heat exchange part 201 flow pipe 204 low-temperature cooling water flow passage (first cooling medium flow passage)
204d, 204h, 204k Low temperature side U-turn section (first cooling medium U-turn section)
205 high temperature cooling water flow path (second cooling medium flow path)
205d High temperature side U-turn part (second cooling medium U-turn part)
205g protrusion

Claims (7)

An intercooler for cooling the supercharged intake air by exchanging heat between the supercharged intake air supercharged to the engine (10) by a supercharger and a cooling medium,
A heat exchange part (200) for exchanging heat between the cooling medium flowing inside the flow passage pipe (201) and the supercharged intake air flowing outside the flow passage pipe,
The cooling medium includes a first cooling medium and a second cooling medium having a temperature higher than that of the first cooling medium,
In the flow passage pipe, a first cooling medium flow passage (204) through which the first cooling medium flows so as to intersect with the flow direction of the supercharged intake air, and the first cooling medium flow passage (204) so as to intersect with the flow direction of the supercharged intake air. A second cooling medium flow path (205) through which the second cooling medium flows is formed,
The second cooling medium flow path is arranged upstream of the first cooling medium flow path in the flow direction of the supercharged intake air,
A fin (207) is provided inside the first cooling medium passage, and no fin is provided inside the second cooling medium passage .
The second cooling medium flow path,
A second cooling medium U-turn part (205d) for making a U-turn of the second cooling medium,
In the second cooling medium U-turn part, a column part (206) is formed, which joins the facing inner surfaces with each other while keeping a predetermined gap,
An intercooler in which inner surfaces of portions (205e, 205f) where the flow direction of the second cooling medium and the flow direction of the supercharged intake air intersect are formed flat . An intercooler for cooling the supercharged intake air by exchanging heat between the supercharged intake air supercharged to the engine (10) by a supercharger and a cooling medium,
A heat exchange part (200) for exchanging heat between the cooling medium flowing inside the flow passage pipe (201) and the supercharged intake air flowing outside the flow passage pipe,
The cooling medium includes a first cooling medium and a second cooling medium having a temperature higher than that of the first cooling medium,
In the flow passage pipe, a first cooling medium flow passage (204) through which the first cooling medium flows so as to intersect with the flow direction of the supercharged intake air, and the first cooling medium flow passage (204) so as to intersect with the flow direction of the supercharged intake air. A second cooling medium flow path (205) through which the second cooling medium flows is formed,
The second cooling medium flow path is arranged upstream of the first cooling medium flow path in the flow direction of the supercharged intake air,
A fin (207) is provided inside the first cooling medium passage, and no fin is provided inside the second cooling medium passage .
The second cooling medium flow path,
A second cooling medium U-turn part (205d) for making a U-turn of the second cooling medium,
In the second cooling medium U-turn part, a column part (206) is formed, which joins the facing inner surfaces with each other while keeping a predetermined gap,
An intercooler in which a protrusion (205g) is formed on an inner surface of a portion (205e, 205f) where the flow direction of the second cooling medium and the flow direction of the supercharged intake air intersect . The length (D _HT ) in the flow direction of the supercharged intake air in the portion where the second cooling medium passage is formed in the passage pipe forms the first cooling medium passage in the passage pipe. is the at site are turbocharged the flow direction length (D _LT) intercooler according to claim 1 or 2 is shorter than. The said 1st cooling medium flow path has the 1st cooling medium U-turn part (204d, 204f, 204h) which makes the said 1st cooling medium U-turn , The any one of Claim 1 thru| or 3 characterized by the above-mentioned. Intercooler. The intercooler according to claim 4 , wherein the first cooling medium flow path has two first cooling medium U-turn parts (204d, 204f). The intercooler according to claim 4 , wherein the first cooling medium passage has three first cooling medium U-turn parts (204d, 204f, 204h). The intercooler according to any one of claims 1 to 3, wherein the first cooling medium flow path causes the first cooling medium to flow in one direction.

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