JP6582778B2 - Engine cooling system - Google Patents

Description

  The present invention relates to an engine cooling system applied to a vehicle engine or the like.

  Generally, a vehicular engine cooling system includes a water pump, an engine internal flow path disposed downstream of the water pump, and a cooling circuit including a radiator disposed downstream of the engine internal flow path. Then, cooling water is sequentially sent from the water pump to the engine internal flow path and the radiator, and then returned to the water pump. For convenience, the water pump, the radiator, and the cooling circuit are referred to as a first water pump, a first radiator, and a first cooling circuit, respectively.

JP-A-6-81648

  On the other hand, a water-cooled intercooler that cools intake air by exchanging heat with cooling water is known. In order to send cooling water to the intercooler, it is conceivable to additionally provide a second cooling circuit. In this case, as the configuration of the second cooling circuit, the inlet portion branched from the outlet side of the first water pump, the second radiator arranged downstream of the inlet portion, and the water cooling type arranged downstream of the second radiator One having an intercooler and an outlet portion arranged downstream of the intercooler and joined to the inlet side of the first water pump is conceivable.

  When such a configuration is adopted, it is effective to make the flow rate of the cooling water flowing through the second cooling circuit smaller than the flow rate of the cooling water flowing through the first cooling circuit. Because the retention time of the cooling water in the second radiator can be lengthened, the temperature of the cooling water discharged from the second radiator can be lowered below the temperature of the cooling water in the first cooling circuit, and the cooling performance of the water cooling intercooler can be improved. It is. Moreover, it is because a cooler cooling water can be made to merge with a 1st cooling circuit, and can be made to flow into an engine internal flow path, and the engine cooling performance can also be improved. Thus, the second cooling circuit has an assist effect that assists the cooling performance of the first cooling circuit.

  However, when the above configuration is adopted, there are the following problems. That is, when the flow rate of the cooling water flowing through the second cooling circuit is increased, more low-temperature cooling water is joined to the first cooling circuit, and the cooling performance of the engine can be improved. However, on the other hand, the residence time of the cooling water in the second radiator is shortened, the cooling performance of the intercooler is lowered, and the intake air temperature rises. That is, the cooling performance of the engine and the intake air temperature are in a trade-off relationship with the flow rate of the cooling water flowing through the second cooling circuit.

  Accordingly, the present invention has been made in view of such circumstances, and an object thereof is to provide an engine cooling system capable of improving the cooling performance of the engine and simultaneously reducing the intake air temperature.

According to one aspect of the invention,
A first cooling circuit comprising: a first water pump; an engine internal passage disposed downstream of the first water pump; and a first radiator disposed downstream of the engine internal passage. A first cooling circuit configured to sequentially send cooling water from one water pump to the flow path in the engine and the first radiator, and then return to the first water pump;
An inlet portion branched from the outlet side of the first water pump, a second radiator disposed downstream of the inlet portion, and a downstream portion of the second radiator and joined to the inlet side of the first water pump A second cooling circuit having an outlet portion to be
A branch portion branched from the outlet side of the second radiator, a flow control valve disposed in the branch portion, a third radiator disposed on the downstream side of the flow control valve, and disposed on the downstream side of the third radiator. A water-cooled intercooler, and a third cooling circuit having a joining portion arranged on the downstream side of the intercooler and joined to the inlet side of the first water pump;
An engine cooling system is provided.

  Preferably, the flow rate of the cooling water passing through the third radiator is made smaller than the flow rate of the cooling water joined from the outlet portion to the inlet side of the first water pump.

  Preferably, the second radiator and the third radiator are integrated.

Preferably, the second radiator and the third radiator are formed as a common integrated radiator,
The integrated radiator is
A first header and a second header;
A radiator core connecting the first and second headers;
A first partition that divides the first header into a second radiator section and a third radiator section;
A second partition that divides the second header into a second radiator portion and a third radiator portion;
An outlet provided in the second radiator of the first header for discharging cooling water;
With
The branching portion is provided in the integrated radiator so as to communicate the outlet of the second radiator portion in the first header and the third radiator portion.

Preferably, the integral radiator further includes a third partition that divides the second radiator portion of the first header into an inlet side and an outlet side,
The outlet is provided on the outlet side of the second radiator portion of the first header.

  According to the present invention, an excellent effect of improving the cooling performance of the engine and simultaneously reducing the intake air temperature is exhibited.

It is a schematic block diagram which shows the cooling system of the engine which concerns on a comparative example. It is a graph which shows the relationship of trade-off. It is a schematic structure figure showing an engine cooling system concerning an embodiment of the present invention. It is a schematic block diagram which shows an integrated radiator. It is a schematic block diagram which shows the equivalent circuit of the cooling system of FIG. It is a schematic block diagram which shows the modification of an integrated radiator.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  First, for convenience, before describing the embodiments of the present invention, comparative examples assumed before the idea of the present invention will be described.

  FIG. 1 is a schematic configuration diagram illustrating an engine cooling system according to a comparative example. Such a cooling system is applied to an engine mounted on a vehicle.

  As shown in the figure, the cooling system 1 includes a first cooling circuit X and a second cooling circuit Y through which engine coolant is circulated or circulated. The first cooling circuit X is a circuit mainly for cooling the engine 2, and the second cooling circuit Y mainly sends cooling water to the water-cooled intercooler 3, and intake air that passes through the intercooler 3. This is a circuit for performing cooling. The intercooler 3 transmits the heat of the intake air I introduced from the intake air inlet 3A to the cooling water, and discharges the intake air I whose temperature has been lowered through the intake air outlet 3B. The engine 2 has a turbocharger (not shown), and is cooled when intake air whose temperature has risen due to supercharging of the turbocharger passes through the intercooler 3.

  The first cooling circuit X is disposed on the first water pump (W / P) 4, the engine internal flow path 5 disposed on the downstream side of the first water pump 4, and the downstream side of the engine internal flow path 5. A first radiator 6 as a high-temperature radiator (HT), and configured to sequentially send cooling water from the first water pump 4 to the engine internal flow path 5 and the first radiator 6, and then return to the first water pump 4. Has been.

  Specifically, the first water pump 4 is installed in the engine 2 and driven by a crankshaft, and is disposed at the upstream end of a loop-shaped engine internal flow path 5 formed inside the engine. And at the time of a drive, a cooling water is discharged to the flow path 5 in an engine. A thermostat (T / S) 7 is provided on the downstream side of the engine internal flow path 5, and when the valve is opened, cooling water that has become hot after engine cooling is sent to the first radiator 6. The thermostat 7 is connected to the inlet of the first radiator 6 via the inlet pipe 8. The outlet of the first radiator 6 is connected to the inlet of the first water pump 4 via the outlet pipe 9. The flow direction of the cooling water A flowing through the first cooling circuit X is indicated by an arrow in the figure.

  The second cooling circuit Y includes an inlet portion 11 branched from the outlet side of the first water pump 4, a second radiator 12 serving as a low-temperature radiator (LT) disposed on the downstream side of the inlet portion 11, and a second radiator. 12 includes the above-described intercooler 3 disposed on the downstream side, and an outlet portion 13 disposed on the downstream side of the intercooler 3 and joined to the inlet side of the first water pump 4. A branch point of the inlet portion 11 is indicated by P1, and a junction point of the outlet portion 13 is indicated by P2. The flow direction of the cooling water B flowing through the second cooling circuit Y is indicated by an arrow in the figure.

  The “outlet side of the first water pump 4” is the position of the flow path at or near the outlet of the first water pump 4, and before the cooling water receives heat from the engine 2 and substantially increases its temperature. The flow path position. Therefore, it includes the upstream side or upstream end of the engine internal flow path 5 as shown. Further, when the first water pump 4 and the engine internal flow path 5 are connected not directly but via a pipe, such a flow path in the pipe is also included in the “exit side of the first water pump 4”. Further, “the inlet side of the first water pump 4” refers to the flow path position at the inlet of the first water pump 4 or the upstream side of the first water pump 4 and downstream of the outlet of the first radiator 6. Therefore, it includes the flow path in the outlet pipe 9 described above.

  The inlet of the second radiator 12 is connected via an inlet pipe 14 to the upstream end of the engine internal flow path 5, particularly to the branch point P1. Therefore, the upstream end portion of the inlet pipe 14 forms the aforementioned inlet portion 11. The outlet of the second radiator 12 is connected to the cooling water inlet of the intercooler 3 via the outlet pipe 15. The cooling water outlet of the intercooler 3 is connected to the outlet pipe 9, particularly its junction P <b> 2 via the pipe 16. Therefore, the downstream end portion of the pipe 16 forms the outlet portion 13 described above.

  In the configuration of this comparative example, when the first water pump 4 is driven when the thermostat 7 is opened, the coolant flows from the first water pump 4 to the engine internal flow path 5, the thermostat 7, the inlet pipe 8, and the first radiator. 6, flows in the outlet pipe 9 in order, and returns to the first water pump 4. That is, the cooling water is circulated in the first cooling circuit X. In this process, the cooling water that has received heat from the engine 2 in the engine internal flow path 5 and becomes high temperature is cooled by exchanging heat with outside air when passing through the first radiator 6.

  On the other hand, the cooling water branched from the engine internal flow path 5 to the inlet pipe 14 at the branch point P1 flows in order through the inlet pipe 14, the second radiator 12, the intercooler 3, and the pipe 16 to the outlet pipe 9 at the junction P2. Merged. In this process, the cooling water is cooled by exchanging heat with the outside air when passing through the second radiator 12, and the cooled cooling water exchanges heat with the intake air in the intercooler 3 to cool the intake air.

  Here, the second cooling circuit Y is configured such that the flow rate of the cooling water B flowing through the second cooling circuit Y is smaller than the flow rate of the cooling water A flowing through the first cooling circuit X. In addition, the 1st cooling circuit X here is except the part (the 1st water pump 4 is in the middle) between the junction P2 and the branch point P1 in a cooling water flow direction among the 1st cooling circuits X. Say part.

  If it carries out like this, the residence time in the 2nd radiator 12 of the cooling water B of the 2nd cooling circuit Y will become long, and the temperature of the cooling water B discharged | emitted from the 2nd radiator 12 will be the temperature of the cooling water A of the 1st cooling circuit X. Less than. Since the cooling water whose temperature has decreased is sent to the intercooler 3, the cooling performance of the intercooler 3 can be improved, and the temperature of the intake air discharged from the intercooler 3 can be reduced. This is advantageous for improving the charging efficiency of intake air.

  In addition, although the temperature rises slightly in the intercooler 3, the cooling water whose temperature has been reduced in this way is merged with the first cooling circuit X, so the temperature of the cooling water A flowing through the first cooling circuit X is also lowered. . Specifically, on the inlet side of the first water pump 4, the cooling water B of the second cooling circuit Y whose temperature has decreased is merged with the first cooling circuit X, and the temperature of the cooling water A of the first cooling circuit X decreases. Is done. The cooling performance of the engine can be improved by the first water pump 4 supplying the cooling water A whose temperature has decreased to the in-engine flow path 5. As described above, the second cooling circuit Y has an assist effect for assisting the cooling performance of the first cooling circuit X to the first radiator 6. By using such a second cooling circuit Y, the temperature of the cooling water A (referred to as engine outlet temperature) exiting from the engine internal flow path 5 and the cooling water flowing into the first radiator 6 are compared with the case where this is not used. The temperature of A (referred to as the first radiator inlet temperature) also decreases. In general, the temperature of the cooling water B of the second cooling circuit Y is lower than the temperature of the cooling water A of the first cooling circuit X.

  However, this comparative example has the following problems. That is, when the flow rate of the cooling water B flowing through the second cooling circuit Y is increased, more low-temperature cooling water is joined to the first cooling circuit X, and the cooling performance of the engine can be improved. However, on the other hand, the residence time of the cooling water B in the 2nd radiator 12 becomes short, and the temperature of the cooling water B discharged | emitted from the 2nd radiator 12 rises. As a result, the cooling performance of the intercooler 3 decreases, and the intake air temperature increases. That is, the cooling performance of the engine and the intake air temperature have a trade-off relationship with the flow rate of the cooling water B flowing through the second cooling circuit Y.

  This trade-off relationship is shown in FIG. The horizontal axis of the graph is the flow rate QB of the cooling water B flowing through the second cooling circuit Y, and the vertical axis is the temperature. In the figure, a line a indicates the first radiator inlet temperature TH, and a line b indicates the intake air temperature Ta. It is assumed that the flow rate of the cooling water A in the first cooling circuit X is constant. As shown in the figure, as the flow rate QB of the second cooling circuit Y increases, the first radiator inlet temperature TH tends to decrease, but the intake air temperature Ta tends to increase. From the viewpoint of engine cooling performance, a high flow rate QB2 is preferable, but from the viewpoint of intake air temperature, it is preferable to set a low flow rate QB1. Thus, the requirements of both are incompatible, and the configuration of the comparative example is not necessarily preferable if both are desired to be compatible.

  In order to solve this problem, the present inventor has come up with the present invention. Embodiments of the present invention will be described below.

  FIG. 3 is a schematic configuration diagram showing an engine cooling system according to an embodiment of the present invention. Such a cooling system is based on a comparative cooling system. In the following description, the same parts as those in the comparative example are denoted by the same reference numerals in the drawing, and the description thereof will be omitted. The description will focus on differences from the comparative example.

  FIG. 5 is a schematic configuration diagram showing an equivalent circuit of the cooling system of FIG. For convenience of description, description will be made with reference to FIG.

  The cooling system 1 according to the present embodiment also includes a first cooling circuit X and a second cooling circuit Y. The configuration of the first cooling circuit X is the same as that of the comparative example. However, unlike the comparative example, the second cooling circuit Y does not include the intercooler 3 and functions as an assist-only circuit that provides the aforementioned assist effect.

  The second cooling circuit Y of the present embodiment includes an inlet portion 11 branched from the outlet side of the first water pump 4 at the position of the branch point P1, and a first low-temperature radiator or intermediate temperature arranged downstream of the inlet portion 11. A second radiator 12 serving as a radiator (LT1), and an outlet portion 13 that is disposed downstream of the second radiator 12 and merges at the position of the merge point P2 on the inlet side of the first water pump 4 are provided. The flow direction of the cooling water B flowing through the second cooling circuit Y is indicated by an arrow in the figure. The outlet part 13 is joined to the outlet pipe 9 at the position of the joining point P2.

  In addition, the cooling system 1 according to the present embodiment includes a third cooling circuit Z for intake air cooling in the intercooler 3. The third cooling circuit Z includes a branch portion 41 branched from the outlet side of the second radiator 12, a flow control valve 42 disposed in the branch portion 41, and a second low-temperature radiator disposed downstream of the flow control valve 42. Alternatively, the third radiator 43 as a low-temperature radiator (LT2), the water-cooled intercooler 3 disposed on the downstream side of the third radiator 43, and the downstream side of the intercooler 3 are joined to the inlet side of the first water pump 4. The merging portion 44 is provided. The flow direction of the cooling water C flowing through the third cooling circuit Z is indicated by arrows in the figure. The merge portion 44 merges with the outlet pipe 9 at the position of the merge point P3. In the present embodiment, the position of the merge point P3 is set downstream from the position of the merge point P2 in the cooling water flow direction in the outlet pipe 9, but this may be reversed. The “exit side of the second radiator 12” refers to the position of the flow path from the outlet of the second radiator 12 in the flow direction of the cooling water B or a position in the vicinity thereof to the junction P2.

  In the second cooling circuit Y, the inlet pipe 14 connects the branch point P <b> 1 and the inlet of the second radiator 12. Therefore, the upstream end portion of the inlet pipe 14 forms the inlet portion 11. An outlet pipe 45 connects the outlet of the second radiator 12 and the junction P2. Therefore, the downstream end portion of the outlet pipe 45 forms the outlet portion 13.

  In the third cooling circuit Z, a pipe 46 connects the outlet of the third radiator 43 and the cooling water inlet of the intercooler 3. A pipe 47 connects the coolant outlet of the intercooler 3 and the junction P3. Therefore, the downstream end portion of the pipe 47 forms the merge portion 44.

  The flow rate control valve 42 is a valve for controlling the flow rate of the cooling water flowing through the branch portion 41, and more specifically, is a kind of throttle valve that changes the flow passage cross-sectional area of the branch portion 41. The opening degree of the flow control valve 42 is controlled by an electronic control unit (ECU) 100 that forms a control unit or a control unit.

  When the opening degree of the flow rate control valve 42 is decreased, the flow rate of the cooling water C passing through the branch portion 41 and thus the third radiator 43 decreases, and the residence time of the cooling water in the third radiator 43 becomes longer. As a result, the temperature of the cooling water discharged from the third radiator 43 can be lowered, and the cooling water whose temperature has been lowered can be supplied to the intercooler 3 to improve the cooling performance of the intercooler 3.

  In this embodiment, the 2nd radiator 12 and the 3rd radiator 43 are integrated, and it forms in the common integrated radiator 30 as shown in FIG. As a result, the entire system can be simplified and made compact. The configuration of the actual cooling system 1 provided with this integrated radiator 30 is shown in FIG.

  As shown in FIG. 4, in the present embodiment, the integrated radiator 30 is a so-called cross-flow type in which the cooling water flows in the horizontal direction, but may be a so-called down-flow type in which the cooling water flows from top to bottom. Good.

  The integrated radiator 30 includes a pair of left and right headers 31 and 32 (a first header 31 on the left side and a second header 32 on the right side), and a radiator core 33 that couples the pair of headers 31 and 32. As is well known, the radiator core 33 has a plurality of tubes (not shown) that connect the left and right headers 31 and 32, and cooling fins (not shown) attached to the tubes. The radiator core 33 or the plurality of tubes are provided over the entire length in the longitudinal direction (vertical direction) of the left and right headers 31 and 32.

  The integrated radiator 30 includes a first partition wall 34 that divides the left first header 31 into a second radiator portion 31A and a third radiator portion 31B, and a right second header 32 that is divided into a second radiator portion 32A and a third radiator. It has the 2nd partition 35 divided | segmented into the part 32B. The first and second partition walls 34 and 35 are provided inside the first and second headers 31 and 32, respectively, and partition the space inside the headers 31 and 32 vertically. In this way, in the integrated radiator 30, the second radiator 12 is formed by the portion above the partition walls 34, 35, and the third radiator 43 is formed by the portion below the partition walls 34, 35.

  The radiator core 33 is not particularly divided, and the radiator core 33 simply has tubes arranged in a plurality of rows over the entire length of the headers 31 and 32 as in the case of a normal radiator. Accordingly, the dividing line a shown in the drawing is a line drawn for convenience only to show the boundary between the second radiator 12 and the third radiator 43, and has a structure as shown by the dividing line a. There is no reason to partition. In other words, the integrated radiator 30 of the present embodiment forms the two radiators 12 and 43 only by dividing the headers 31 and 32 by the partition walls 34 and 35. Thereby, two radiators can be formed in one radiator with a simple configuration.

  With respect to the second radiator 12, the second radiator 31A of the first header 31 is provided with a third partition wall 29 that divides the second radiator 31A into an upper inlet side and a lower outlet side. An inlet 36 of the second radiator 12 is provided on the upper inlet side, and an outlet 37 of the second radiator 12 is provided on the lower outlet side. A downstream end of the inlet pipe 14 is connected to the inlet 36, and cooling water is introduced. An upstream end of the outlet pipe 45 is connected to the outlet 37, and cooling water is discharged from the outlet 37.

  The second radiator 32A of the second header 32 is not provided with the partition wall as described above. Accordingly, the cooling water flowing from the inlet 36 to the inlet side of the second radiator portion 31A flows in the right direction in the upper tube of the radiator core 33 as indicated by the arrow, and the second radiator portion 32A of the second header 32. , Then flows leftward through the middle tube of the radiator core 33, flows into the second radiator portion 31 </ b> A of the first header 32, and is discharged from the outlet 37. Thus, the second radiator 12 has a two-pass structure in which the cooling water is U-turned in the second radiator portion 32A and passes through the radiator core 33 twice.

  As described above, there is no structure for partitioning the radiator core 33 into the upper stage and the middle stage. For convenience, only the dividing line b that divides these is displayed in the figure.

  On the other hand, the above-described flow control valve 42 is provided in the first partition wall 34 of the first header 31. The flow path inside the flow control valve 42 substantially forms the above-described branch portion 41. Thus, the branch part 41 or the flow control valve 42 is provided in the 1st partition 34 so that the exit 37 thru | or outlet side of the 2nd radiator part 31A in the 1st header 31 and the 3rd radiator part 31B may be connected. Yes.

  With respect to the third radiator 43, an outlet 38 of the third radiator 43 is provided in the third radiator portion 32 </ b> B of the second header 32. An upstream end of the pipe 46 is connected to the outlet 38, and cooling water is discharged from the outlet 38.

  The cooling water that has flowed into the third radiator portion 31B from the outlet side of the second radiator portion 31A through the flow rate control valve 42 flows rightward in the lower tube of the radiator core 33, as indicated by the arrow, and the second header 32. Into the third radiator 32B and discharged from the outlet 38. Thus, the third radiator 43 has a one-pass structure that allows the cooling water to pass through the radiator core 33 only once. The integral radiator 30 has a three-pass structure in which the cooling water is passed through the radiator core 33 three times.

  In the present embodiment, as shown in the figure, the second radiator 12 has a larger heat radiation area than the third radiator 43 and has a higher cooling performance. It should be noted that the integrated radiator 30 of the present embodiment is not a combination of the first radiator 6 (high temperature radiator) of the first cooling circuit X.

  In FIG. 3, an inlet 36 and an outlet 37 of the second radiator 12 and an outlet 38 of the third radiator 43 are shown. From the above description, it will be understood that the configuration of FIG. 3 with the integrated radiator 30 of FIG. 4 is equivalent to the configuration of FIG.

  According to the configuration of the present embodiment, the cooling water branched at the branch point P <b> 1 flows into the integrated radiator 30 from the inlet 36 through the inlet pipe 14 and is cooled in the process of passing through the second radiator 12. After this cooling, the flow is divided into a flow (B) discharged from the outlet 37 of the second radiator 12 and a flow (C) flowing into the third radiator 43 through the flow rate control valve 42. The flow that has flowed into the third radiator 43 is further cooled in the process of passing through the third radiator 43 and is discharged from the outlet 38.

  As described above, the flow discharged from the outlet 38 of the third radiator 43 is lower in temperature than the flow discharged from the outlet 37 of the second radiator 12. Therefore, by supplying the latter to the intercooler 3 through the pipe 46, the cooling performance of the intercooler 3 can be improved and the intake air temperature can be lowered. After passing through the intercooler, the coolant passes through the pipe 47 and then joins the outlet pipe 9 at the junction P3. This also can assist the engine cooling performance of the first cooling circuit X.

  On the other hand, the flow discharged from the outlet 37 of the second radiator 12 passes through the outlet pipe 45 and then joins the outlet pipe 9 at the junction P2. Thus, by supplying the cooling water B cooled by the second radiator 12 to the first cooling circuit X, the engine cooling performance of the first cooling circuit X can be assisted.

  In this sense, the temperature of the cooling water B discharged from the outlet 37 of the second radiator 12 can be referred to as an intermediate temperature, and the temperature of the cooling water C discharged from the outlet 38 of the third radiator 43 can be referred to as a low temperature. On the other hand, the temperature of the cooling water A discharged from the outlet of the first radiator 6 can be referred to as a high temperature.

  In the present embodiment, preferably, the flow rate of the cooling water C passing through the third radiator 43 is made smaller than the flow rate of the cooling water B joined from the outlet portion 13 to the inlet side of the first water pump 4. Specifically, the flow rate of the cooling water C discharged from the outlet 38 of the third radiator 43 is made smaller than the flow rate of the cooling water B discharged from the outlet 37 of the second radiator 12. The opening degree of the flow rate control valve 42 is controlled so that the flow rates of the cooling waters B and C are obtained. Then, the aforementioned trade-off problem can be effectively solved.

  That is, referring to FIG. 2, the flow rate of the cooling water B discharged from the outlet 37 of the second radiator 12 is, for example, a relatively large QB2 in order to improve the engine cooling performance. In the comparative example, the intake air temperature Ta is increased at the flow rate QB2, but in the present embodiment, since the intercooler 3 is not included in the second cooling circuit Y, it is not necessary to increase the intake air temperature Ta. Only the assist effect of the first cooling circuit X is obtained by the second cooling circuit Y. On the other hand, the flow rate of the cooling water C discharged from the outlet 38 of the third radiator 43 is set to a value equal to, for example, a relatively small QB1. Thereby, the residence time of the cooling water C in the 3rd radiator 43 can be lengthened, and the intake air temperature Ta can be reduced. Thus, according to the present embodiment, it is possible to improve the cooling performance of the engine and simultaneously reduce the intake air temperature.

  In addition, the following can be considered as a control method of the flow control valve 42. For example, when the engine load is a low / medium load of a predetermined value or less and it is desired to prioritize the intake air cooling over the engine cooling, the opening degree of the flow control valve 42 is decreased to a predetermined value or less to cool the third radiator 43. The residence time of water is lengthened, and the temperature of the cooling water C discharged from the outlet 38 of the third radiator 43 is lowered. Thereby, intake temperature can be reduced effectively. The engine load can be detected by ECU 100 by inputting a signal such as the fuel injection amount to ECU 100.

  Further, for example, when the engine load is a high load exceeding a predetermined value and the state continues for a relatively long time and the engine is likely to overheat, that is, when it is desired to give priority to engine cooling over intake air cooling, the flow control valve 42 The opening degree is decreased to a predetermined value or less, and the flow rate of the cooling water B discharged from the outlet 37 of the second radiator 12 is increased. Thereby, the cooling water B whose temperature has decreased can be merged into the first cooling circuit X at a relatively large flow rate, and the engine can be cooled with a large assist effect.

  Further, for example, when the boost pressure exceeds a predetermined value continues for a relatively long time and there is a possibility that the cooling water will boil in the intercooler 3, that is, the cooling water boiling suppression in the intercooler 3 is suppressed rather than the engine cooling. When priority is to be given, the opening degree of the flow control valve 42 is increased more than a predetermined value, and the flow rate of the cooling water C discharged from the outlet 38 of the third radiator 43 is increased. Thereby, the comparatively large flow volume of the cooling water C can be supplied to the intercooler 3, and boiling of the cooling water in the intercooler 3 can be suppressed or prevented.

  Although the embodiments of the present invention have been described in detail above, various other embodiments of the present invention are conceivable.

  (1) For example, the second radiator 12 and the third radiator 43 are separated without being integrated, and a pipe or the like is added between them to directly form a circuit or system as shown in FIG. May be.

  (2) The configuration of the integrated radiator 30 may be a two-pass structure as shown in FIG. In this case, the third partition wall 29 is omitted, and the inlet 36 of the second radiator 12 is provided in the second radiator portion 32 </ b> A of the second header 32. Since the other configuration is the same as that shown in FIG. 4, the same reference numerals are given to the same parts, and the description is omitted.

  (3) In the example shown in FIG. 4, the flow rate control valve 42 (and the branching portion 41) is provided inside the integrated radiator 30, but it can also be provided outside. For example, a pipe forming the branching portion 41 can be provided outside the integrated radiator 30 and the flow control valve 42 can be provided in the pipe.

  (4) The present invention can also be applied to cooling systems other than those for vehicles. The first water pump 4 may be electric.

  The embodiment of the present invention is not limited to the above-described embodiment, and includes all modifications, applications, and equivalents included in the concept of the present invention defined by the claims. Therefore, the present invention should not be construed as being limited, and can be applied to any other technique belonging to the scope of the idea of the present invention.

DESCRIPTION OF SYMBOLS 1 Cooling system 2 Engine 3 Water-cooled intercooler 4 1st water pump 5 Engine internal flow path 6 1st radiator 11 Inlet part 12 2nd radiator 13 Outlet part 29 3rd partition 30 Integrated radiator 31 1st header 31A 2nd radiator Part 31B third radiator part 32 second header 32A second radiator part 32B third radiator part 33 radiator core 34 first partition 35 second partition 37 outlet 41 branching part 42 flow control valve 43 third radiator 44 merge part X first Cooling circuit Y Second cooling circuit Z Third cooling circuit

Claims (4)

A first cooling circuit comprising: a first water pump; an engine internal passage disposed downstream of the first water pump; and a first radiator disposed downstream of the engine internal passage. A first cooling circuit configured to sequentially send cooling water from one water pump to the flow path in the engine and the first radiator, and then return to the first water pump;
An inlet portion branched from the outlet side of the first water pump, a second radiator disposed downstream of the inlet portion, and a downstream portion of the second radiator and joined to the inlet side of the first water pump A second cooling circuit having an outlet portion to be
A branch portion branched from the outlet side of the second radiator, a flow control valve disposed in the branch portion, a third radiator disposed on the downstream side of the flow control valve, and disposed on the downstream side of the third radiator. A water-cooled intercooler, and a third cooling circuit having a joining portion arranged on the downstream side of the intercooler and joined to the inlet side of the first water pump;
A control unit for controlling the flow rate control valve;
Equipped with a,
The engine cooling system , wherein the control unit increases the opening degree of the flow control valve larger than a predetermined value when a state in which the boost pressure exceeds a predetermined value continues . The engine cooling system according to claim 1 , wherein the second radiator and the third radiator are integrated. The second radiator and the third radiator are formed as a common integrated radiator,
The integrated radiator is
A first header and a second header;
A radiator core connecting the first and second headers;
A first partition that divides the first header into a second radiator section and a third radiator section;
A second partition that divides the second header into a second radiator portion and a third radiator portion;
An outlet provided in the second radiator of the first header for discharging cooling water;
With
3. The engine cooling according to claim 2 , wherein the branch portion is provided in the integrated radiator so as to communicate the outlet of the second radiator portion and the third radiator portion in the first header. system. The integral radiator further includes a third partition that divides the second radiator portion of the first header into an inlet side and an outlet side,
The engine cooling system according to claim 3 , wherein the outlet is provided on an outlet side of the second radiator portion of the first header.

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