JP4292888B2 - Engine cooling system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an engine cooling apparatus having a radiator or the like, and belongs to the field of engine cooling technology.
[0002]
[Prior art]
In automobiles, etc., cooling water is usually circulated between the water jacket of the engine and the radiator by a water pump to cool the engine. In that case, in order to improve warm-up at the time of cold start The flow rate of the cooling water may be controlled. For example, Patent Document 1 discloses a method for reducing the flow rate of the cooling water to the engine when the engine is cold started. According to this, at the time of cold start, cooling of the engine is suppressed and warm-up is promoted.
[0003]
In Patent Document 2 and Patent Document 3, a cooling water circulation passage between an engine water jacket and a radiator is provided for the purpose of preventing cooling water from being cooled by a radiator during cold start. In addition to providing a bypass passage that bypasses the radiator, a temperature sensing valve is provided at the junction of the bypass passage and the circulation passage. During cold start, the passage leading to the radiator is closed and the bypass passage is opened, so that the cooling water does not pass through the radiator. Is disclosed to circulate to the water jacket of the engine through the bypass passage.
[0004]
By the way, on the cooling water circulation passage, not only the above-mentioned radiator, but also, for example, as shown in Patent Document 4, a heater core for heating the vehicle interior using warmed cooling water, engine oil, and transmission oil There may be provided a heat exchanger or the like for exchanging heat with the cooling water. In this case, the cooling water is oil or the like when it is cold even if the configuration as in Patent Documents 1 to 3 is adopted. It is cooled by the heat exchange with it and hinders warm-up promotion.
[0005]
Therefore, in order to further improve engine warm-up at cold start, etc., it is conceivable to completely stop the circulation of the cooling water so that the heat deprived by the heat exchanger or the heater core is eliminated. In Patent Document 5, the water pump is electrified so that it can be started and stopped regardless of the operating state of the engine, and the water pump is operated at a cold start when the temperature of the cooling water is low. What is stopped is disclosed. On the other hand, when a mechanical water pump is used, if the valves for closing these passages are provided on the cooling water circulation passage and the bypass passage, etc., cooling is performed during engine operation as with the electric water pump. Water circulation can be stopped completely.
[0006]
According to this, the cooling water warmed by the heat generated by the combustion is prevented from being cooled by heat exchange with oil or the like, the engine warms up quickly, and the fuel increase during cold is unnecessary. The fuel consumption can be improved. Further, in an engine in which a catalyst device is provided in the exhaust passage, a decrease in exhaust temperature is suppressed, the catalyst device is activated early, and emissions can be improved.
[0007]
[Patent Document 1]
JP 2002-138835 A
[Patent Document 2]
Japanese Utility Model Publication No. 3-38474
[Patent Document 3]
Japanese Utility Model Publication No. 55-41570
[Patent Document 4]
JP 2001-280133 A
[Patent Document 5]
JP 2002-161748 A
[0008]
[Problems to be solved by the invention]
However, in these cases, after starting the engine, there is a problem of when the electric water pump is operated and when the valves are opened, in other words, when cooling water is passed through the circulation passage. In other words, if the timing of passing water through the circulation passage is too early, engine warm-up will be delayed, and as a result, fuel increase will be required for a long time, fuel consumption will be reduced, and activation of the catalyst device will be delayed and emissions will be delayed. It will get worse. On the other hand, if the timing of passing water through the circulation passage is too slow, for example, when engine oil or transmission oil is warmed by heat exchange with cooling water, the oil is delayed warming up, resulting in poor control response of the transmission, etc. Such problems arise.
[0009]
By the way, after warming up, if the exhaust temperature becomes too high, the durability of exhaust system members and the like may be adversely affected. To prevent this, it is possible to enrich the air-fuel ratio and perform exhaust cooling at high exhaust temperatures. is there. However, since such control deteriorates fuel consumption, it is not preferable to positively execute this control.
[0010]
Therefore, it is conceivable to provide an exhaust water jacket for cooling the exhaust in the vicinity of the exhaust passage. In this case, however, the exhaust is cooled and hinders activation of the catalyst device in the cold state.
[0011]
Accordingly, the present invention provides an engine that can achieve early warm-up of the engine and early activation of the catalyst device and early temperature rise of the engine oil and transmission oil even when the exhaust water jacket is provided. It is an object of the present invention to provide a cooling device.
[0012]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention is configured as follows.
[0013]
First, the invention according to claim 1 of the present application includes a cooling water circulation passage for circulating cooling water by means of a water pump via a first water jacket and a radiator provided near the combustion chamber of the engine, and the circulation passage. Branching between the cooling water outlet of the first water jacket and the cooling water inlet of the radiator and connected to the suction side of the water pump in the circulation passage, and provided with a heat exchanger and a heater for room heating in parallel. An auxiliary passage, a temperature sensing valve provided upstream or downstream of the radiator in the circulation passage and closed when the temperature of the cooling water is equal to or lower than a first predetermined temperature, and provided in the auxiliary passage to the heat exchanger. A heat exchange control valve that controls the amount of cooling water to be supplied, a heater control valve that is also provided in the auxiliary passage and controls the amount of cooling water supplied to the heater, a heat exchange control valve, and An engine cooling device comprising a control means for controlling the heater control valve and having a catalyst device on the exhaust passage, wherein the cooling device is in parallel with the first water jacket in the circulation passage or on the auxiliary passage. A second water jacket for cooling the vicinity of the exhaust passage upstream of the catalyst device is provided in series with the heat exchanger and the heater, and determination means for determining whether or not the catalyst device is activated is provided. And the control means is a heater control valve when cold. Close control In addition, it is determined that the catalyst device has been activated by the determination means during the cold period from when the engine is started until the temperature of the cooling water rises to a second predetermined temperature lower than the first predetermined temperature. The heat exchange control valve during at least one period Close control It is characterized by doing.
[0014]
According to this invention, when cold, the heater control valve is Close control In addition, during the cold period from when the engine is started until the temperature of the cooling water rises to a second predetermined temperature lower than the first predetermined temperature, the catalyst device is activated by the determination means During at least one of the periods until it is determined that the heat exchange control valve is Close control So, when cold, cooling water No longer circulating The cooling water heated by the heat generated by the combustion is prevented from being cooled by heat exchange with oil or the like. As a result, the warm-up of the engine proceeds promptly, and it is not necessary to increase the amount of fuel when it is cold, thereby improving fuel efficiency. Further, in an engine in which a catalyst device is provided in the exhaust passage, a decrease in exhaust temperature is suppressed, the catalyst device is activated early, and emissions can be improved.
[0015]
The second predetermined temperature may be, for example, a temperature at which the catalytic device is almost activated after the engine is cold started. According to this, when the cooling water rises above the second predetermined temperature, the catalyst device is also almost activated, and when it is determined that the catalyst device is activated, the cooling water is also almost second predetermined temperature. This means that the temperature has risen to the vicinity of the temperature, and the effects of both the activation of the catalyst device and the rise of the cooling water temperature to the second predetermined temperature can be obtained almost simultaneously. Moreover, the above-mentioned effect will be achieved more reliably if both are satisfied.
[0016]
When the temperature of the cooling water becomes equal to or higher than the second predetermined temperature, the heat exchange control valve is opened, so that the temperature of the engine oil or transmission oil rises quickly due to heat exchange with the cooling water. . In that case, the heater control valve Close control Therefore, the heat of the cooling water is not taken away by the heater, but is used for heat exchange with the engine oil or the transmission oil, so that the temperature of the oil rises more effectively.
[0017]
Further, when the temperature of the cooling water becomes equal to or higher than the first predetermined temperature, the temperature sensing valve is opened, the cooling water is cooled by the radiator, the engine is cooled by the cooled cooling water, and the engine oil and the speed change are performed. The machine oil is cooled by the cooling water. In this case, since the exhaust gas is actively cooled by the second water jacket, it is possible to suppress the execution of air-fuel ratio enrichment to prevent the exhaust system members from being deteriorated in durability, and the fuel consumption, particularly the engine load is large and the exhaust temperature is large. This will improve the fuel efficiency during high-speed driving, where the temperature tends to rise.
[0018]
The invention according to claim 2 of the present application is the invention according to claim 1, wherein when the second water jacket is provided on the auxiliary passage, the second water jacket is at least upstream of the heat exchanger. It is arranged on the side.
[0019]
According to this invention, since the second water jacket is provided on the upstream side of the heat exchanger, the engine oil and the transmission oil can be effectively warmed by the cooling water just warmed in the second water jacket. it can.
[0020]
The invention according to claim 3 of the present application is the invention according to claim 1 or 2, wherein the second water jacket is formed on an interposed member interposed between the cylinder head and the exhaust manifold. It is characterized by being.
[0021]
According to the present invention, the second water jacket can be easily provided without making a large design change to the cylinder head of the existing engine.
[0022]
By the way, in the engine cooling device described in Patent Document 2, a transmission oil heat exchanger that cools transmission oil that requires a higher temperature than the engine oil is provided downstream of the engine oil heat exchanger. Therefore, when these heat exchangers are used as oil warmers, the transmission oil heat exchangers are cooled by heat exchange with engine oil in the engine oil heat exchanger. Since water is supplied, the transmission oil cannot be sufficiently warmed by the transmission oil heat exchanger.
[0023]
Accordingly, the invention according to claim 4 of the present application is the invention according to any one of claims 1 to 3, wherein a heat exchanger for transmission oil and a heat exchanger for engine oil are provided as heat exchangers. These heat exchangers are arranged in series, and the transmission oil heat exchanger is arranged upstream of the engine oil heat exchanger.
[0024]
According to the present invention, the transmission oil heat exchanger that performs heat exchange of the transmission oil that requires a higher temperature than the engine oil is provided on the upstream side of the engine oil heat exchanger. It will be warmed in preference to engine oil. That is, the transmission oil that requires a higher temperature than the engine oil can be quickly raised to the required temperature.
[0025]
The invention according to claim 5 of the present application is the invention according to any one of claims 1 to 3, wherein a heat exchanger for transmission oil and a heat exchanger for engine oil are provided as heat exchangers. These heat exchangers are arranged in parallel, and the heat exchange control valve is provided with a passage provided with a heat exchanger for transmission oil and a passage provided with a heat exchanger for engine oil. And after the engine is warmed up, the control means opens the transmission oil heat exchange control valve when the temperature of the transmission oil is higher than a third predetermined temperature, The heat exchange control valve is configured to open when the temperature of the engine oil is higher than a fourth predetermined temperature, and the third predetermined temperature is higher than the fourth predetermined temperature. To do.
[0026]
According to the present invention, the temperature of the transmission oil and the temperature of the engine oil can be individually controlled according to the respective states, and, after warming up, the temperature of the transmission oil is set to the temperature of the engine oil. The controllability of the transmission can be improved by maintaining the temperature higher than that.
[0027]
Further, in the invention described in claim 6 of the present application, in the invention described in claim 5, the third predetermined temperature is lower when the engine speed is low near the idle speed than when the engine speed is high. It is said that it is said.
[0028]
According to the present invention, a decrease in transmission oil pressure due to the third predetermined temperature being a constant value is prevented. That is, when the engine speed is reduced to a speed near the idle speed, the pressure of the transmission oil generated by the rotation is also reduced. In this case, when the temperature of the transmission oil is high, a leak caused by a decrease in viscosity Will further reduce the transmission oil pressure and reduce the required pressure. Get lost There is a fear. However, in the present invention, the first predetermined temperature for opening the heat exchange control valve in the passage on the side where the heat exchanger for transmission oil is provided is set to be lower at low speeds near the idle speed than at high engine speeds. Since the value is low, the transmission oil is more effectively cooled at the time of low rotation near the idle rotation than at the time of high rotation, and the pressure drop of the transmission oil is suppressed.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
As shown in FIG. 1, the vehicle according to the first embodiment is equipped with a water-cooled engine 1 and an automatic transmission 2, and a catalyst device 4 is provided on an exhaust passage 3 of the engine 1. It has been.
[0030]
The cooling device for the engine 1 includes a cooling water circulation passage 10 that circulates cooling water, a centrifugal water pump 11 that is driven via a belt by the crankshaft of the engine 1 and circulates the cooling water in the circulation passage 10. A radiator 12 that cools the cooling water is provided, and the water pump 11 circulates the cooling water through the water jacket 1 a that cools the vicinity of the combustion chamber of the engine 1 and the radiator 12. On the first main passage 13 that connects the cooling water inlet 1b of the water jacket 1a and the cooling water outlet 12a of the radiator 12 in the cooling water circulation passage 10, a temperature sensing valve that opens when the cooling water temperature is equal to or higher than a predetermined temperature T1. 15 is provided. Further, the engine 1 is provided with an exhaust water jacket 1d that cools the upstream side of the catalyst device 4 in the exhaust passage 3 from the upstream portion of the water jacket 1a, and cooling water for the exhaust water jacket 1d is provided. Outlet 1 e and second main passage 14 that connects cooling water outlet 1 c of water jacket 1 a and cooling water inlet 12 b of radiator 12 in the circulation passage 10 are connected via a branch passage 14 a.
[0031]
An auxiliary passage 20 is provided between the second main passage 14 and the water pump 11 and the temperature sensing valve 15 in the first main passage 13. The auxiliary passage 20 includes a heat exchange passage 21 and a heater passage 22 which are provided in parallel and are joined together on the upstream side and the downstream side. In the heat exchange passage 21, an electromagnetic heat exchange control valve 23, a transmission oil heat exchanger 24 that performs heat exchange between the cooling water and transmission oil, An engine oil heat exchanger 25 that performs heat exchange between water and engine oil is provided. The heater passage 22 is provided with an electromagnetic heater control valve 26 and an indoor heating heater core 27 in order from the upstream side through which the cooling water circulates. The automatic transmission 2 and the transmission oil heat exchanger 24 are connected by an oil passage (not shown). When the automatic transmission 2 is operated, the transmission oil is converted into the automatic transmission 2 and the transmission oil. It circulates between the heat exchanger 24 for use. The engine 1 and the engine oil heat exchanger 25 are connected by an oil passage (not shown). When the engine 1 is operated, the engine oil is exchanged between the engine 1 and the engine oil heat exchanger 25. Circulate.
[0032]
Next, the structure of the engine 1 will be briefly described. As shown in FIGS. 1 and 2, the engine 1 is an in-line four-cylinder type engine, which is defined by a cylinder block 31 and a cylinder head 32. It has four combustion chambers 33. Each combustion chamber 33... 33 communicates with two intake ports 34 and two exhaust ports 35, and intake valves 36, 36 and exhaust valves 37, which open and close these intake ports 34, 34 and exhaust ports 35, 35. 37 is provided.
[0033]
Further, cooling water passages 38, 39, and 40 are formed in the side walls of the cylinder block 31 and the cylinder head 32 as water jackets 1a for cooling the vicinity of the combustion chambers 33. In the upper and lower portions of the exhaust ports 35, 35, flat cooling water passages 41, 42 are formed along the exhaust port 35 as a water jacket 1d for cooling the vicinity of the exhaust port 35. The cooling water passages 41, 42 extend in the longitudinal direction of the engine 1 in the cylinder head 32, the upstream side merges with the cooling water passages 38, 39, 40 in the cylinder head 32, and the downstream side is one end surface of the cylinder head 32. To the second main passage 14 via the branch passage 14a.
[0034]
As shown in FIG. 3, a control unit 100 that controls the heater control valve 26 and the heat exchange control valve 23 is mounted on the cooling device of the engine 1. The control unit 100 is disposed in the vicinity of the catalyst device 4 on the exhaust passage 3 in the vicinity of the catalyst device 4, the signal of the water temperature sensor 110 that measures the engine water temperature, the signal of the oil temperature sensor 120 that detects the temperature of the automatic transmission oil. The signals of the first and second O2 sensors 130 and 140 that detect the active state, the signal of the engine rotation sensor 150 that detects the engine speed, and the like are input.
[0035]
Next, the control of the heat exchange control valve 23 by the control unit 100 will be described using the flowchart of FIG. As will be described later, the control unit 100 closes the heater control valve 26 when the control is cold.
[0036]
First, when the ignition key is turned on by the driver, the coolant temperature before starting the engine 1 is detected from the signal of the water temperature sensor 110 in step S1. Next, in step S2, it is determined whether or not the detected cooling water temperature is equal to or higher than a predetermined value T2. If YES, that is, if the detected cooling water temperature is equal to or higher than the predetermined value T2, heat exchange is performed in step S3. The control valve 23 is opened and the engine 1 is started. Here, the predetermined value T2 is a value lower than the predetermined value T1 of the temperature at which the temperature sensing valve opens.
[0037]
On the other hand, when the determination in step S2 is NO, that is, when the detected coolant temperature is lower than the predetermined value T2, in step S4, the heat exchange control valve 23 is closed and the engine 1 is started, and in step S5, the timer is started. Start. Next, in step S6, various state quantities such as the cooling water temperature after starting the engine 1 and the engine speed are detected by the various sensors 110 to 150. In step S7, the detected two O2 sensors 130 and 140 are detected. And the current water pressure is calculated based on the current cooling water temperature and the engine speed.
[0038]
Next, in steps S8 to S11, various determinations are made based on the various state quantities detected in step S6, the calculation result in step S7, and the like. That is, in step S8, as in step S2, it is determined whether or not the detected cooling water temperature is equal to or higher than a predetermined value T2, and in step S9, the catalyst device 4 is determined based on the activity of the catalyst device 4 calculated in step S6. In step S10, it is determined whether or not the water pressure calculated in step S7 is equal to or greater than a predetermined value. In step S11, it is determined whether or not the timer has timed out. If any one of the determination results in these steps is YES, the heat exchange control valve 23 is opened in step S12. On the other hand, when both determinations are NO, the processes after step S7 are repeatedly executed until YES is determined in any of these steps S8 to S11.
[0039]
That is, when the cooling water temperature rises to the predetermined value T2 or more, the engine 1 is warmed up, the fuel consumption increase correction becomes unnecessary, and the engine oil and the transmission oil can be warmed. In order to further improve the fuel consumption of the power plant as a whole, the heat exchange control valve 23 is opened to raise the temperature of the engine oil and the transmission oil.
[0040]
In addition, when the catalyst device 4 is activated, and the exhaust gas purification capacity of the catalyst device 4 has reached a predetermined capacity, the heat exchange control valve is then used to further improve the fuel consumption of the power plant as a whole. 23 is opened to raise the temperature of the engine oil and transmission oil.
[0041]
In the present embodiment, the predetermined value T2 is a temperature at which the catalytic device 4 is almost activated after the engine 1 is started when the engine 1 is cold. According to this, the cooling water temperature is predetermined. If either condition of the case where the value rises to the value T2 or more and the case where the catalyst device 4 is activated is satisfied, both conditions are substantially satisfied. That is, it is possible to obtain both effects of improving fuel consumption and improving emissions.
[0042]
Further, when the water pressure exceeds a predetermined value, the water pressure may cause disconnection of pipes and hoses constituting the plurality of passages 13, 14 and the like. To prevent this, the heat exchange control valve 23 is used. Is opened. Here, the predetermined value of the water pressure corresponds to, for example, the water pressure when the cooling water temperature is 25 degrees and the engine speed is 3000 rpm, and the water pressure when the cooling water temperature is 90 ° C. and the engine speed is 2000 rpm.
[0043]
On the other hand, if the timer expires without the catalyst device being determined to have been activated, or without the water pressure being determined to be greater than or equal to the predetermined value, the engine oil and the transmission oil will be delayed due to the temperature rise delay. The heat exchange control valve 23 is opened because there is a possibility of hindering improvement in fuel consumption.
[0044]
That is, the control unit 100 opens the heat exchange control valve 23 simultaneously with the start when the cooling water temperature is equal to or higher than the predetermined value T2 when the engine is started in the cold state, and when the cooling water temperature at the start is equal to or lower than the predetermined value T2. When the heat exchange control valve 23 is closed and then it is determined that the catalytic device 4 has been activated based on the signals from the first and second O2 sensors 130 and 140, and the cooling water temperature has become equal to or higher than the predetermined value T2. The heat exchange control valve 23 is opened when any of the conditions when the water pressure becomes equal to or higher than the predetermined value and when the timer expires is satisfied.
[0045]
Next, the control of the heat exchange control valve 23 and the control of the heater control valve 26 after the heat exchange control valve 23 is opened will be described. That is, after opening the heat exchange control valve 23, the control unit 100 controls the heat exchange control valve 23 according to the temperature of the subsequent cooling water and the temperature of the transmission oil. That is, the heat exchange control valve 23 is opened when the temperature of the transmission oil is lower than the temperature of the cooling water, and is closed when the temperature of the transmission oil is higher than the temperature of the cooling water and lower than the predetermined temperature T3. When the temperature of the oil is higher than the predetermined temperature T3, it opens (see FIG. 7). According to such control, the temperature of the transmission oil rises rapidly by heat exchange with the cooling water when the temperature is lower than the temperature of the cooling water after a predetermined period has elapsed since the engine 1 was started. When the temperature is higher than the temperature of the cooling water and lower than the predetermined temperature T3, it is not cooled by the cooling water and rises as the temperature of the transmission rises. When the temperature is higher than the predetermined temperature T3, the water is cooled by the cooling water. The rise will be suppressed.
[0046]
The control unit 100 controls the heater control valve 26 to be closed when it is cold, and closes the transmission oil when the temperature of the transmission oil is lower than the temperature of the cooling water. Higher than the predetermined temperature T3, and closed when the transmission oil temperature is higher than the predetermined temperature T3. That is, the effect produced by the heat exchange control valve 23 is further ensured by setting the state almost opposite to that of the heat exchange control valve 23.
[0047]
Further, the control unit 100 determines that the catalyst device 4 is activated based on the signals from the first and second O2 sensors 130 and 140 when the driver turns on the indoor heating switch. The heater control valve 26 is opened on the condition that This is because, in a state where the catalyst device 4 is not activated, the heater 27 is not warmed, and even if it is operated, only cold air is blown. Therefore, the activation of the catalyst device 4 is prioritized. .
[0048]
Next, the operation of the engine cooling device according to the first embodiment will be described.
[0049]
First, when the ignition key is turned on by the driver, the engine 1 is started.
[0050]
In this case, as shown in FIG. 2, the mixture of air and fuel is filled into the combustion chamber 33 via the intake ports 34, 34 when the intake valves 36, 36 are lifted, and the combustion chamber 33 is filled with the air / fuel mixture. The high-temperature exhaust gas after combustion combusts the exhaust manifold 43 attached to the cylinder head 30, the catalyst device 4, and a silencer (not shown) via the exhaust ports 35 and 35 when the exhaust valves 37 and 37 are lifted. It will be discharged into the atmosphere via an exhaust member such as.
[0051]
In this case, for the cooling water system, the heater control valve 26 and the heat exchange control valve 23 are closed under the control of the control unit 100 when the cooling water temperature at the time of starting the engine is lower than the predetermined value T2. At this time, the temperature sensing valve 15 is closed because the coolant temperature is lower than the first predetermined value T1. In this case, the cooling water is not circulated in any of the passages.
[0052]
According to this, at the time of cold start, the cooling water warmed by the heat generated by the combustion is prevented from being cooled by heat exchange with oil or the like, so that the cooling water as shown in FIG. As the water temperature rises quickly and the engine warms up rapidly, the temperature of the exhaust gas is prevented from lowering and the catalyst device 4 is activated early. As a result, it is not necessary to increase the amount of fuel in the cold state or increase the amount of fuel for the early activation of the catalyst, which not only improves fuel consumption but also prevents emission deterioration.
[0053]
On the other hand, when the heater control valve 26, the heat exchange control valve 23, and the temperature sensing valve 15 are closed, the engine rotation becomes, for example, 2000 rotations or more by the driver's accelerator operation or the like, and the discharge pressure of the water pump 11 is high. When the water pressure becomes equal to or higher than the predetermined pressure, the heat exchange control valve 23 is opened, and the cooling water is supplied from the water pump 11 to the first main passage 13, the water jackets 1a, 1d, the first, as shown in FIG. It will recirculate | return to the water pump 11 through the 2 main channel | path 14, the heat exchange channel | path 21, and the 1st main channel | path 13 (a circulation path is shown with a white arrow in the figure, and so on).
[0054]
According to this, even when the cooling water pressure rises when the circulation of the cooling water is stopped by the valves, problems such as detachment of the passage constituent members such as the hose and the pipe are prevented.
[0055]
Further, when it is determined that the catalyst device 4 is activated based on signals from the first and second O2 sensors 130 and 140, when the cooling water temperature becomes equal to or higher than the predetermined value T2, or the timer has timed out. When the heat exchange control valve 23 is opened. At this time, the heater control valve 26 remains closed, and the temperature sensing valve 15 is still closed because the coolant temperature is still lower than T1. In this case, the cooling water flows through the circulation path of FIG.
[0056]
According to this, as indicated by the reference symbol in FIG. 7, the engine oil and transmission oil have a higher temperature than the oil by the engine oil heat exchanger 25 and the transmission oil heat exchanger 24. It will be warmed by heat exchange with the cooling water. In this case, since the transmission oil heat exchanger 24 that requires a higher temperature than the engine oil is provided on the upstream side of the engine oil heat exchanger 25, the transmission oil is warmed in preference to the engine oil. It will be. That is, the temperature of the transmission oil that requires a higher temperature than the engine oil can be raised to a required temperature at an early stage. Further, since the cooling water does not circulate in the radiator 12 and the heater core 27, almost all the heat of the cooling water can be used for heat exchange between the engine oil and the transmission oil.
[0057]
When it is determined from the signals of the water temperature sensor 110 and the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the cooling water temperature, the heat exchange control valve 23 is closed and the heater control valve 26 is opened. . The temperature sensing valve 15 is in an open state because the coolant temperature has risen above the valve opening temperature T1.
[0058]
In this case, as shown in FIG. 5, the cooling water is supplied from the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the heater passage 22, and the first main passage 13. While returning to the pump 11, it returns to the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the radiator 12, and the first main passage 13.
[0059]
According to this, indoor heating can be performed by the heater core 27, and the cooling water is cooled by the radiator 12. Further, as indicated by the reference numeral in FIG. 7, the engine oil and the transmission oil continue to rise in temperature without being cooled by the cooling water.
[0060]
Then, when it is determined from the signal of the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the predetermined temperature T3 (for example, such a state occurs when the engine load is large), the heat exchange control valve 23 Is opened and the heater control valve 26 is closed. The temperature sensing valve 15 is in an open state because the coolant temperature is equal to or higher than T1.
[0061]
In this case, as shown in FIG. 6, the cooling water is supplied from the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the heat exchange passage 21, and the first main passage 13. While returning to the water pump 11, the water pump 11 is returned to the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the radiator 12, and the first main passage 13.
[0062]
That is, when the load is high after warming up, it is possible to allow a sufficient amount of cooling water to flow through the radiator 12 and the heat exchange passage 21 by preventing the cooling water from flowing through the heater passage 22. Thus, the cooling water can be sufficiently cooled by the radiator 12. Further, the transmission oil heat exchanger 24 and the engine oil heat exchanger 25 can cool the transmission oil and the engine oil below the heat-resistant temperature To of the oil, as indicated by reference numerals in FIG. The deterioration of these oils can be prevented.
[0063]
Further, the engine 1 is also effectively cooled by the sufficiently cooled cooling water. As a result, it is not necessary to enrich the air-fuel ratio for preventing the deterioration of the transmission oil and the engine oil. Improved fuel efficiency when driving.
[0064]
Note that, as shown in FIG. 8, the predetermined temperature T3 is set to a lower value at the time of low rotation near the idle rotation than at the time of high engine rotation. According to this, a decrease in the pressure of the transmission oil due to the constant temperature at which the heat exchange control valve 23 opens after the engine warms up at the predetermined temperature T3 is prevented. In other words, when the engine speed is reduced to a speed near the idle speed, the hydraulic pressure generated by the rotation also decreases. In this case, when the temperature of the transmission oil is high, the hydraulic pressure is further increased due to a leak due to a decrease in viscosity. There is a risk that the required oil pressure may not be obtained due to the decrease. However, in the present embodiment, the predetermined temperature T3 for opening the heat exchange control valve 23 is set to a lower value at the time of low rotation near the idle rotation than at the time of high engine rotation. During rotation, the transmission oil is cooled more effectively than during high rotation, and a reduction in hydraulic pressure of the transmission oil is suppressed.
[0065]
Further, in the present embodiment, the heat exchange control valve 23 is opened when any one of the steps S8 to S11 is satisfied, but both of the steps S8 and S9 are determined as YES. When this occurs, the heat exchange control valve 23 may be opened, and according to this, both the effects of improving fuel consumption and reducing emissions can be achieved more reliably.
[0066]
Next, a second embodiment will be described. Note that the same or similar components as those in the first embodiment will be described using the same reference numerals.
[0067]
That is, the engine cooling device according to the second embodiment, like the first embodiment, has a belt formed by a cooling water circulation passage 10 for circulating cooling water and a crankshaft of the engine 1 as shown in FIG. A centrifugal water pump 11 that circulates cooling water in the circulation passage 10 and a radiator 12 that cools the cooling water. The water pump 11 cools the vicinity of the combustion chamber of the engine 1. Cooling water is circulated through the water jacket 1 a and the radiator 12. On the first main passage 13, there is provided a temperature sensing valve 15 that opens when the coolant temperature is equal to or higher than a predetermined temperature T1.
[0068]
In that case, in the second embodiment, an exhaust water jacket 1 d ′ that cools the exhaust passage 3 upstream of the catalyst device 4 is provided in an adapter 50 that is a separate member from the cylinder head 32. . That is, as shown in FIGS. 9 and 10, the adapter 50 is interposed between the cylinder head 32 ′ and the exhaust manifold 43 ′, and the exhaust port 35 of the cylinder head 32 ′ and the exhaust manifold 43 ′ are exhausted. The exhaust passage 51 communicates with the passage, and has flat cooling water passages 52 and 53 extending in the longitudinal direction of the engine 1 as the exhaust water jacket 1d ′.
[0069]
An auxiliary passage 20 is provided between the second main passage 14 and the water pump 11 and the temperature sensing valve 15 in the first main passage 13, and the exhaust water jacket 1 d ′ is provided on the auxiliary passage 20. . The water jacket 1 d ′ is connected to the connection passage 20 a that forms the upstream portion of the auxiliary passage 20 on the cooling water inlet 1 f side, and the heat exchange passage 21 and the heater passage 22 that form the downstream portion of the auxiliary passage 20 on the cooling water outlet 1 g side. Are connected in series to the junction.
[0070]
In the heat exchange passage 21, an electromagnetic heat exchange control valve 23, and an automatic transmission oil heat exchanger 24 that performs heat exchange between the cooling water and the automatic transmission oil, in order from the upstream side where the cooling water circulates, An engine oil heat exchanger 25 that performs heat exchange between the cooling water and the engine oil is provided. The heater passage 22 is provided with an electromagnetic heater control valve 26 and an indoor heating heater core 27 in order from the upstream side through which the cooling water circulates.
[0071]
The configuration of the controller, sensor, and the like is the same as in the first embodiment, and the heat exchange control valve 23 and the heater control valve 26 are controlled in the same manner as in the first embodiment according to the flowchart of FIG. The
[0072]
According to this, when the coolant temperature at the time of starting the engine is less than the predetermined value T2, the heater control valve 26 and the heat exchange control valve 23 are closed under the control of the control unit 100. At this time, the temperature sensing valve 15 is closed because the coolant temperature is lower than the first predetermined value T1. In this case, the cooling water is not circulated in any of the passages.
[0073]
Further, when it is determined that the catalyst device 4 is activated based on the signals from the first and second O2 sensors 130 and 140, when the cooling water temperature becomes equal to or higher than the predetermined value T2, the water pressure becomes equal to or higher than the predetermined pressure. Or when the timer expires, the heat exchange control valve 23 is opened. At this time, the heater control valve 26 remains closed, and the temperature sensing valve 15 is still closed because the coolant temperature is still lower than T1.
[0074]
In this case, as shown in FIG. 9, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 20a, the exhaust water jacket 1d, the heat exchange passage 21, The water is returned to the water pump 11 through the main passage 13.
[0075]
When it is determined from the signals of the water temperature sensor 110 and the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the cooling water temperature, the heat exchange control valve 23 is closed and the heater control valve 26 is opened. . The temperature sensing valve 15 is in an open state because the coolant temperature has risen above the valve opening temperature T1.
[0076]
In this case, as shown in FIG. 11, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 20a, the exhaust water jacket 1d ', the heater passage 22, Recirculation to the water pump 11 through the first main passage 13 and recirculation to the water pump 11 through the first main passage 13, the water jacket 1 a, the second main passage 14, the radiator 12, and the first main passage 13; Become.
[0077]
Then, when it is determined from the signal of the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the predetermined temperature T3 (for example, such a state occurs when the engine load is large), the heat exchange control valve 23 Is opened and the heater control valve 26 is closed. The temperature sensing valve 15 is in an open state because the coolant temperature is equal to or higher than T1.
[0078]
In this case, as shown in FIG. 12, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 20a, the exhaust water jacket 1d ', the heat exchange passage 21, While returning to the water pump 11 via the first main passage 13, returning to the water pump 11 via the first main passage 13, the water jacket 1 a, the second main passage 14, the radiator 12, and the first main passage 13. It becomes.
[0079]
In particular, according to the configuration of the second embodiment, in addition to the effects described in the first embodiment, an adapter 50 is interposed between the cylinder head 32 'and the exhaust manifold 43'. Since the cooling water passages 52 and 53 as the exhaust water jacket 1d ′ are formed in the adapter 50, the exhaust water jacket can be easily provided without making a major design change to the cylinder head of the existing engine.
[0080]
Next, a third embodiment will be described.
[0081]
The engine cooling apparatus according to the third embodiment is obtained by changing the configuration of the auxiliary passage 20 and the like according to the first embodiment. That is, as shown in FIG. 13, the auxiliary passage 60 of the engine cooling device according to the third embodiment includes a heat exchange passage 61 for the transmission oil heat exchanger 24 and an engine oil heat exchanger 25. The heat exchanger passage 62 and the heater passage 22 are provided in parallel, and control valves 63, 64, and 26 are provided upstream of the heat exchangers 24 and 25 and the heater 27, respectively. Other configurations are the same as those of the first embodiment. It is the same as the first embodiment or Similar Components will be described using the same reference numerals as those in the first embodiment.
[0082]
As shown in FIG. 13, a control unit 100 ′ for controlling the heater control valve 26 and the heat exchange control valves 63 and 64 is mounted on the cooling device for the engine 1 according to the third embodiment. The control unit 100 ′ includes a signal from the water temperature sensor 110 that detects the engine water temperature, a signal from the oil temperature sensor 120 that detects the temperature of the automatic transmission oil, a signal from the oil temperature sensor 125 that detects the temperature of the engine oil, and the exhaust. A signal of the first and second O2 sensors 130 and 140 that are disposed in the vicinity of the catalyst device 4 on the passage 3 and detects the active state of the catalyst device 4, and a signal of the engine rotation sensor 150 that detects the engine speed. Enter etc.
[0083]
In the third embodiment, the heat exchange control valves 63 and 64 and the heater control valve 26 are the heat exchange control valve 23 and the heater control of the first embodiment, unless otherwise specified. The heat exchange control valve controlled in accordance with the valve 26 and described in the flowchart of FIG. 4 means both the heat exchange control valves 63 and 64.
[0084]
According to this, when the coolant temperature at the time of starting the engine is lower than the predetermined value T2, the heater control valve 26 and the heat exchange control valves 63 and 64 are closed by the control of the control unit 100 ′. At this time, the temperature sensing valve 15 is closed because the coolant temperature is lower than the first predetermined value T1. In this case, the cooling water is not circulated in any of the passages.
[0085]
Further, when it is determined that the catalyst device 4 is activated based on the signals from the first and second O2 sensors 130 and 140, the water pressure becomes equal to or higher than the predetermined pressure when the cooling water temperature becomes equal to or higher than the predetermined value T2. When the timer expires, the heat exchange control valves 63 and 64 are opened. At this time, the heater control valve 26 remains closed, and the temperature sensing valve 15 is still closed because the coolant temperature is still lower than T1.
[0086]
In this case, as shown in FIG. 13, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the heat exchange passages 61 and 62, and the first main passage 13. It will recirculate | reflux to the water pump 11 via this.
[0087]
When it is determined from the signals of the water temperature sensor 110 and the transmission oil temperature sensor 120 that the transmission oil temperature is higher than the cooling water temperature, the heat exchange control valves 63 and 64 are closed, while the heater control valve 26 is be opened. The temperature sensing valve 15 is in an open state because the coolant temperature has risen above the valve opening temperature T1.
[0088]
In this case, as shown in FIG. 15, the cooling water is supplied from the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the heater passage 22, and the first main passage 13. While returning to the pump 11, it returns to the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the radiator 12, and the first main passage 13.
[0089]
When it is determined from the signal of the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the predetermined temperature T3, the heat exchange control valves 63 and 64 are opened, and the heater control valve 26 is closed. The temperature sensing valve 15 is in an open state because the coolant temperature is equal to or higher than T1.
[0090]
In this case, as shown in FIG. 16, the cooling water is supplied from the water pump 11 through the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the heat exchange passages 61 and 62, and the first main passage 13. As a result, the water pump 11 is returned to the water pump 11 and also returned to the water pump 11 via the first main passage 13, the water jackets 1 a and 1 d, the second main passage 14, the radiator 12, and the first main passage 13.
[0091]
In the third embodiment, the engine or the like is sufficiently warmed up, the temperatures of the transmission oil and engine oil are higher than the cooling water temperature, and the heat exchange control valves 63 and 64 are closed. In FIG. 17, the temperature when both the oils are further increased and the heat exchange control valves 63 and 64 are opened again has been described as the same. However, as shown in FIG. 17, a transmission oil heat exchanger 24 is provided. The predetermined temperature at which the heat exchange control valve 63 in the heat exchange passage 61 is opened is T3, and the predetermined temperature at which the heat exchange control valve 64 in the heat exchange passage 62 in which the engine oil heat exchanger 25 is provided is T4. Alternatively, the values may be individually controlled as different values. In this case, for example, if the predetermined temperature T3 for opening the heat exchange control valve 63 in the heat exchange passage 61 is set to a value higher than the predetermined temperature T4 for opening the heat exchange control valve 64 in the heat exchange passage 62, first, the engine oil When the temperature rises to the predetermined temperature T4 (time t1), the heat exchange control valve 64 for the engine opens, and then when the temperature of the transmission oil rises to the predetermined temperature T3 (time t2), The heat exchange control valve 63 is opened. According to this, in a state where the engine is sufficiently warmed up and the engine load becomes large, the temperature of the transmission oil is maintained at a temperature higher than the temperature of the engine oil while preventing the engine oil from overheating. Thus, the controllability of the transmission can be improved.
[0092]
Next, a fourth embodiment will be described.
[0093]
As shown in FIG. 18, the engine cooling device according to the fourth embodiment is a heat exchanger for the transmission oil heat exchanger 24 that constitutes the third embodiment, that is, the auxiliary passage 60. In the case where the passage 61, the heat exchange passage 62 for the engine oil heat exchanger 25, and the heater passage 22 are provided in parallel, the adapter 50 is connected to the exhaust water jacket 1d as in the second embodiment. The cooling water passages 51 and 52 as' are formed, and the others are configured according to the second and third embodiments.
[0094]
In the fourth embodiment, the heat exchange control valves 63 and 64 and the heater control valve 26 are similar to the heat exchange control valves 63 and 64 and the heater control valve 26 of the third embodiment. Be controlled.
[0095]
According to this, when the coolant temperature at the time of starting the engine is lower than the predetermined value T2, the heater control valve 26 and the heat exchange control valves 63 and 64 are closed by the control of the control unit 100 ′. At this time, the temperature sensing valve 15 is closed because the coolant temperature is lower than the first predetermined value T1. In this case, the cooling water is not circulated in any of the passages.
[0096]
Further, when it is determined that the catalyst device 4 is activated based on the signals from the first and second O2 sensors 130 and 140, the water pressure becomes equal to or higher than the predetermined pressure when the cooling water temperature becomes equal to or higher than the predetermined value T2. When the timer expires, the heat exchange control valves 63 and 64 are opened. At this time, the heater control valve 26 remains closed, and the temperature sensing valve 15 is still closed because the coolant temperature is still lower than T1.
[0097]
In this case, as shown in FIG. 18, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 60a, the exhaust water jacket 1d ', the heat exchange passage 61, 62, the water is returned to the water pump 11 through the first main passage 13.
[0098]
When it is determined from the signals of the water temperature sensor 110 and the transmission oil temperature sensor 120 that the transmission oil temperature is higher than the cooling water temperature, the heat exchange control valves 63 and 64 are closed, while the heater control valve 26 is be opened. The temperature sensing valve 15 is in an open state because the coolant temperature has risen above the valve opening temperature T1.
[0099]
In this case, as shown in FIG. 19, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 60a, the exhaust water jacket 1d ', and the second main passage 14. The water pump 11 is returned to the water pump 11 through the heater passage 26 and the first main passage 13, and the water pump is passed through the first main passage 13, the water jacket 1 a, the second main passage 14, the radiator 12, and the first main passage 13. 11 to reflux.
[0100]
When it is determined from the signal of the transmission oil temperature sensor 120 that the temperature of the transmission oil has become higher than the predetermined temperature T3, the heat exchange control valves 63 and 64 are opened, and the heater control valve 26 is closed. The temperature sensing valve 15 is in an open state because the coolant temperature is equal to or higher than T1.
[0101]
In this case, as shown in FIG. 20, the cooling water is supplied from the water pump 11 to the first main passage 13, the water jacket 1a, the second main passage 14, the connection passage 60a, the exhaust water jacket 1d ', the heat exchange passage 61, 62, while returning to the water pump 11 through the first main passage 13 and returning to the water pump 11 through the first main passage 13, the water jacket 1a, the second main passage 14, the radiator 12, and the first main passage 13. Will be.
[0102]
In particular, according to the fourth embodiment, all of the effects described in the first embodiment, the second embodiment, and the third embodiment (transmission oil heat exchanger and The engine oil heat exchanger is arranged in series, and the effect obtained when the transmission oil heat exchanger is provided upstream of the engine oil heat exchanger is obtained.
[0104]
【The invention's effect】
As described above, according to the present invention, when cold, the heater control valve is Close control In addition, during the cold period from when the engine is started until the temperature of the cooling water rises to a second predetermined temperature lower than the first predetermined temperature, the catalyst device is activated by the determination means In at least one of the periods until it is determined that the heat exchange control valve is Close control So, when cold, cooling water No longer circulating The cooling water heated by the heat generated by the combustion is prevented from being cooled by heat exchange with oil or the like. As a result, the warm-up of the engine proceeds promptly, and it is not necessary to increase the amount of fuel when it is cold, thereby improving fuel efficiency. Further, in an engine in which a catalyst device is provided in the exhaust passage, it is possible to suppress the exhaust temperature from being lowered, to activate the catalyst device early, and to improve emissions.
[0105]
When the temperature of the cooling water becomes equal to or higher than the second predetermined temperature, the heat exchange control valve is opened, so that the temperature of the engine oil or transmission oil rises quickly due to heat exchange with the cooling water. . In that case, the heater control valve Close control Therefore, the heat of the cooling water is not taken away by the heater, but is used for heat exchange with the engine oil or the transmission oil, so that the temperature of the oil rises more effectively.
[0106]
Further, when the temperature of the cooling water becomes equal to or higher than the first predetermined temperature, the temperature sensing valve is opened, the cooling water is cooled by the radiator, the engine is cooled by the cooled cooling water, and the engine oil and the speed change are performed. The machine oil is cooled by the cooling water. In this case, since the exhaust gas is actively cooled by the second water jacket, it is possible to suppress the execution of air-fuel ratio enrichment to prevent the exhaust system members from being deteriorated in durability, and the fuel consumption, particularly the engine load is large and the exhaust temperature is large. This will improve the fuel efficiency during high-speed driving, where the temperature tends to rise.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of an engine cooling device according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view of a main part in the vicinity of a cylinder head of the engine according to the first embodiment.
FIG. 3 is a control configuration diagram of a cooling device of the engine.
FIG. 4 is a flowchart showing an example of the control.
FIG. 5 is a diagram showing a circulating state of cooling water when a heat exchange control valve is closed, a heater control valve is opened, and a temperature sensing valve is closed.
FIG. 6 is a diagram showing a circulating state of cooling water when the heat exchange control valve is open, the heater control valve is closed, and the temperature sensing valve is closed.
FIG. 7 is a graph showing changes in engine water temperature and transmission oil temperature after cold start.
FIG. 8 is a characteristic diagram of the opening temperature of the heat exchange control valve with respect to the engine speed.
FIG. 9 is an overall configuration diagram of an engine cooling device according to a second embodiment of the present invention.
FIG. 10 is a cross-sectional view of a principal part in the vicinity of a cylinder head of the engine according to the second embodiment.
FIG. 11 is a diagram showing a circulating state of cooling water when the heat exchange control valve is closed, the heater control valve is opened, and the temperature sensing valve is closed.
FIG. 12 is a view showing a circulating state of cooling water when the heat exchange control valve is open, the heater control valve is closed, and the temperature sensing valve is closed.
FIG. 13 is an overall configuration diagram of an engine cooling device according to a third embodiment of the present invention.
FIG. 14 is a control configuration diagram of an engine cooling device according to the third embodiment;
FIG. 15 is a diagram showing a circulating state of cooling water when the heat exchange control valve is closed, the heater control valve is opened, and the temperature sensing valve is closed.
FIG. 16 is a diagram showing a circulating state of cooling water when the heat exchange control valve is open, the heater control valve is closed, and the temperature sensing valve is closed.
FIG. 17 is a diagram showing changes in engine water temperature, transmission oil temperature, and engine oil temperature after cold start.
FIG. 18 is an overall configuration diagram of an engine cooling device according to a fourth embodiment of the present invention.
FIG. 19 is a diagram showing a circulating state of cooling water when the heat exchange control valve is closed, the heater control valve is opened, and the temperature sensing valve is closed.
FIG. 20 is a diagram showing a circulating state of cooling water when the heat exchange control valve is open, the heater control valve is closed, and the temperature sensing valve is closed.
[Explanation of symbols]
1 engine
1a Water jacket (water jacket that cools the vicinity of the combustion chamber)
1d, 1d 'Exhaust water jacket (water jacket that cools the vicinity of the exhaust passage)
2 Automatic transmission
3 Exhaust passage
4 catalytic equipment
10 Cooling water circulation passage
11 Water pump
12 Radiator
15 Temperature sensing valve
20 Auxiliary passage
21 Heat exchange passage
22 Heater passage
23 Heat exchange control valve
24 Heat exchanger for transmission oil
25 Heat exchanger for engine oil
26 Heater control valve
27 Heater core (heater for room heating)
50 Adapter (Intermediate member)
T1 predetermined temperature (first predetermined temperature related to the temperature sensitive valve)
T2 predetermined temperature (second predetermined temperature related to heat exchange control valve)
T3 predetermined temperature (third predetermined temperature related to heat exchange control valve)
T4 predetermined temperature (fourth predetermined temperature related to heat exchange control valve)

Claims (6)

A cooling water circulation passage for circulating cooling water by a water pump through a first water jacket and a radiator provided in the vicinity of the combustion chamber of the engine, a cooling water outlet of the first water jacket in the circulation passage, and a radiator An auxiliary passage provided in parallel with a heat exchanger and a heater for indoor heating, branched from between the cooling water inlet and the upstream side of the radiator in the circulation passage, or connected to the suction side of the water pump in the circulation passage; A temperature sensing valve provided on the downstream side and closed when the temperature of the cooling water is equal to or lower than a first predetermined temperature; a heat exchange control valve that is provided in the auxiliary passage and controls the amount of cooling water supplied to the heat exchanger; A heater control valve that is also provided in the auxiliary passage and controls the amount of cooling water supplied to the heater, and a heat exchange control valve and a control means for controlling the heater control valve. And a cooling device for an engine provided with a catalyst device on the exhaust passage, in parallel with the first water jacket in the circulation passage or in series with the heat exchanger and the heater on the auxiliary passage. A second water jacket for cooling the vicinity of the exhaust passage upstream of the catalyst device is provided, and determination means for determining whether or not the catalyst device has been activated is provided. The heater control valve is closed and controlled , and the catalyst device determines whether the temperature of the cooling water rises from the start of the engine to the second predetermined temperature lower than the first predetermined temperature. A cooling device for an engine, wherein the heat exchange control valve is controlled to be closed during at least one of a period until it is determined that the heat is activated. The engine cooling apparatus according to claim 1, wherein when the second water jacket is provided on the auxiliary passage, the second water jacket is disposed at least upstream of the heat exchanger. . The engine cooling apparatus according to claim 1 or 2, wherein the second water jacket is formed on an interposed member interposed between the cylinder head and the exhaust manifold. A heat exchanger for transmission oil and a heat exchanger for engine oil are provided as heat exchangers, and these heat exchangers are arranged in series, and the heat exchanger for transmission oil is an engine The engine cooling device according to any one of claims 1 to 3, wherein the engine cooling device is disposed on an upstream side of the oil heat exchanger. A heat exchanger for transmission oil and a heat exchanger for engine oil are provided as heat exchangers, these heat exchangers are arranged in parallel, and the heat exchange control valve is a transmission oil The control means is provided in both the passage provided with the heat exchanger for engine and the passage provided with the heat exchanger for engine oil, and the control means is a heat exchange control valve for transmission oil after the engine is warmed up. The engine oil heat exchange control valve is opened when the temperature of the transmission oil is higher than the third predetermined temperature, and the engine oil heat exchange control valve is opened when the temperature of the engine oil is higher than the fourth predetermined temperature. The engine cooling device according to any one of claims 1 to 3, wherein the third predetermined temperature is higher than the fourth predetermined temperature. 6. The engine cooling apparatus according to claim 5, wherein the third predetermined temperature is set to a lower value when the engine speed is low and close to idle speed than when the engine speed is high.

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