The present invention relates to a cooling system for an engine.
Conventionally, known cooling systems for vehicles form a plurality of coolant flow paths passing through an engine body (cylinder head or cylinder block) or auxiliary machinery (heater core, exhaust gas recirculation (EGR) device, etc.), and are provided with a flow rate control valve for controlling coolant flow rates of the respective coolant flow paths (e.g., JP2013-224643A). Such a cooling system restricts the flow of the coolant into the engine body by the flow rate control valve while the engine is being warmed up after a cold start so as to stimulate a temperature increase of the engine body. When the temperature of the engine body becomes high, the cooling system cancels the flow restriction of the coolant into the engine body so as to cool the engine body. A water pump is disposed upstream of the flow rate control valve and discharges the coolant.
During such a flow restriction, the coolant paths on the upstream side of the flow rate control valve are under a high hydraulic pressure caused by a discharging pressure of the water pump. If the flow restriction is canceled under the high hydraulic pressure, a large amount of coolant temporarily flows into the engine body and causes a temperature decrease of the engine body.
Therefore, with the cooling system of JP2013-224643A, a coolant flow path which passes through the auxiliary machinery but does not pass through the engine body (hereinafter, referred to as “the engine-bypass flow path”) is provided, and the coolant is flowed into the engine-bypass flow path prior to canceling the flow restriction in the flow path passing through the engine body (hereinafter, referred to as “the through-engine flow path”). Thus, overcooling of the engine body by the introduction of the large amount of coolant due to the high hydraulic pressure on the upstream side of the flow rate control valve is suppressed.
Meanwhile, in JP2013-224643A, when the coolant is not flowing into the engine-bypass flow path (when the coolant dwells in the engine-bypass flow path without flowing), the temperature of the coolant within the engine-bypass flow path is low. Therefore, immediately after the flow rate control valve switches the flow path by the flow rate control valve to change the state where the coolant is not flowing into the engine-bypass flow path into a state where the coolant is flowing thereinto, the low-temperature coolant currently dwelling in the engine-bypass flow path without flowing flows into the engine body, and therefore, the temperature of the engine body temporarily decreases, and ignitability of the engine may degrade.
The present invention is made in view of the above situations and aims to provide a cooling system for an engine which can suppress overcooling of an engine body when a flow path of coolant is switched between the engine body and auxiliary machinery after a cold start of the engine.
According to an aspect of the present invention, a cooling system for an engine is provided. The cooling system for the engine includes coolant flow paths, a coolant pump, a flow rate control valve, a temperature detector, and a valve controller. The coolant flow paths include a first flow path and a second flow path and circulate coolant therethrough, the first flow path passing through a cylinder head of the engine, the second flow path branching from the first flow path and passing through auxiliary machinery of the engine. The coolant pump circulates the coolant within the coolant flow paths. The flow rate control valve adjusts a flow rate of the coolant through the second flow path. The temperature detector detects a temperature of the coolant within the first flow path. The valve controller adjusts an opening of the flow rate control valve based on the temperature detected by the temperature detector. When the detected temperature is below a predetermined temperature threshold, the valve controller adjusts the opening of the flow rate control valve to one of zero and a predetermined small opening around zero, and when the detected temperature is one of the temperature threshold and a value thereabove, the valve controller increases the opening of the flow rate control valve to a predetermined target opening in one of a stepwise fashion and a continuous and gradual fashion.
According to this configuration, when the temperature of the coolant flowing through the cylinder head is below the temperature threshold, the opening of the flow rate control valve is adjusted to one of zero and the predetermined small opening around zero. Thus, the flow rate of the coolant flowing through the cylinder head is restricted, and the warming up of the engine is stimulated.
Further, when the temperature of the coolant flowing through the cylinder head is one of the temperature threshold and a value thereabove, the opening of the flow rate control valve is increased to the predetermined target opening in one of the stepwise fashion and the continuous and gradual fashion. Thus, the flow rate restriction of the coolant flowing through the cylinder head is gradually canceled, and a temperature decrease (overcooling) of the cylinder head can be suppressed.
Specifically, when the opening of the flow rate control valve is zero, the coolant does not flow within the second flow path, and when the opening of the flow rate control valve is the predetermined small opening around zero, the flow rate of the coolant within the second flow path is small. In both cases, the coolant warmed up by the heat of the engine after the cold start is restricted from flowing into the second flow path, and the temperature of the coolant within the second flow path is comparatively low. In such a case where the temperature of the coolant within the second flow path is low, if the opening of the flow rate control valve is increased, the flow rate of the coolant flowing through the second flow path is increased, and the amount of low-temperature coolant flowing into the first flow path is increased. However, with the above configuration, since the opening of the flow rate control valve is increased in one of the stepwise fashion and the continuous and gradual fashion, the amount of the low-temperature coolant flowing into the cylinder head is gradually increased. Therefore, the overcooling of the cylinder head is suppressed, and the degradation of the ignitability after the cold start of the engine can be suppressed.
Note that “the opening of the flow rate control valve is increased in the stepwise fashion” means that the opening of the flow rate control valve is increased intermittently in at least two steps. Further, “the opening of the flow rate control valve is increased in the continuous and gradual fashion” means that the opening of the flow rate control valve is increased comparatively moderately and continuously, and does not mean sharply and continuously.
The auxiliary machinery of the engine is preferably disposed at a downstream flow path of the first flow path, the downstream flow path located downstream of the branching point between the first and second flow paths. The flow rate control valve is preferably connected with the downstream flow path and preferably constantly maintains the opening of the valve with respect to the downstream flow path at a predetermined small opening around zero.
According to this configuration, since the opening of the flow rate control valve with respect to the downstream flow path is constantly maintained at the predetermined small opening around zero, a small amount of coolant constantly flows through the downstream flow path. Therefore, by disposing the auxiliary machinery which requires constant cooling by the coolant at the downstream flow path, overheating of the auxiliary machinery can be prevented.
The valve controller preferably opens the flow rate control valve to the second flow path at a predetermined opening that is below the target opening and maintains the opening, and when the detected temperature meets a predetermined condition while the opening of the flow rate control valve is maintained, the valve controller preferably opens the flow rate control valve to the second flow path to reach the target opening.
According to this configuration, since the valve controller opens the flow rate control valve to maintain the opening at the predetermined opening below the target opening for a while, the low-temperature coolant existing within the second flow path is gradually supplied to the cylinder head. Therefore, the overcooling of the cylinder head after the cold start of the engine can be suppressed, and the warming up of the engine can be stimulated.
The auxiliary machinery disposed at the second flow path preferably includes a heater core.
According to this configuration, although the heat of the coolant within the second flow path is taken by the heater core, the coolant is gradually supplied to the cylinder head. Thus, the overcooling of the cylinder head after the cold start of the engine can be suppressed.
The auxiliary machinery disposed at the second flow path preferably includes a radiator.
According to this configuration, although the heat of the coolant within the second flow path is released through the radiator, the coolant is gradually supplied to the cylinder head. Thus, the overcooling of the cylinder head after the cold start of the engine can be suppressed.
The coolant flow paths also preferably include a third flow path passing through a cylinder block of the engine. The flow rate control valve preferably adjusts the flow rate of the coolant through the second and third flow paths. When the detected temperature is below a predetermined temperature threshold for the third flow path, the valve controller preferably adjusts the opening of the flow rate control valve with respect to the third flow path to one of zero and a predetermined small opening around zero, and when the detected temperature is one of the predetermined temperature threshold for the third flow path and a value thereabove, the valve controller preferably increases the opening of the flow rate control valve with respect to the third flow path to a predetermined target opening for the third flow path in one of a stepwise fashion and a continuous and gradual fashion, the predetermined temperature threshold for the third flow path being a value above the target threshold for the first flow path.
According to this configuration, the low-temperature coolant existing within the third flow path when the opening of the flow rate control valve with respect to the third flow path is one of zero and the predetermined small opening around zero, is supplied to the cylinder head and the cylinder block gradually by increasing the opening of the flow rate control valve in one of the stepwise fashion and the continuous and gradual fashion. Thus, the overcooling of the cylinder head and the cylinder block after the cold start of the engine can be suppressed.
The flow rate control valve is preferably a rotary valve for increasing the flow rate of the coolant by increasing an opening thereof.
According to this configuration, since the rotary valve for increasing the flow rate of the coolant by increasing the opening thereof is used as the flow rate control valve, the flow rate can easily be controlled.
Hereinafter, one preferred embodiment of the present invention is described in detail with reference to the appended drawings.
First, an engine 9 and an intake-and-exhaust system thereof according to this embodiment are described.
The engine 9 is a diesel engine for driving a vehicle.
The engine 9 includes a cylinder block 9a formed with a plurality of cylinders (only one cylinder is illustrated in
A piston 9f coupled to a crankshaft 9e via a connecting rod 9d is reciprocatably fitted into each of the cylinders.
In the cylinder head 9b, an intake port 9g, and an exhaust port 9h are formed for each of the cylinders. An intake valve 9j and an exhaust valve 9k are disposed at the intake and exhaust ports 9g and 9h, respectively.
Further, the cylinder head 9b is provided with electromagnetic-type direct injectors 9m for injecting fuel into the respective cylinders. The fuel is supplied to the direct injectors 9m from a fuel tank via a fuel pump and a common rail (none of them illustrated). The common rail is provided with a fuel pressure sensor 36 (see
The intake-and-exhaust system of the engine 9 includes an intake passage 20 for introducing intake air into the cylinders via the intake ports 9g, and an exhaust passage 21 for discharging outdoors exhaust gas produced within the cylinders.
The intake passage 20 is provided, in the following order from the upstream side, with an air cleaner 22 for removing dust contained within the intake air, a compressor 24 of a turbocharger, an intake shutter valve 11b for shutting down the intake passage 20, an intake shutter valve actuator 38 for driving the intake shutter valve 11b, an intercooler 25 for forcibly cooling the intake air at high pressure and temperature due to being compressed by the compressor 24, and an intercooler coolant pump 26 for sending coolant to the intercooler 25.
The exhaust passage 21 is provided, in the following order from the upstream side, with an exhaust turbine 27 of the turbocharger, a diesel oxidation catalyst (DOC) 28, a diesel particulate filter (DPF) 29 for capturing exhaust particulate matter within the exhaust gas, etc.
Further, the intake-and-exhaust system includes a high-pressure exhaust gas recirculation (EGR) device 30 and a low-pressure EGR device 31.
The high-pressure EGR device 30 includes a high-pressure EGR passage 30a connecting a position of the intake passage 20 upstream of the intake ports 9g with a position of the exhaust passage 21 downstream of the exhaust ports 9h, a high-pressure EGR valve 11a for adjusting a flow rate of high-pressure EGR gas through the high-pressure EGR passage 30a, and a high-pressure EGR valve actuator 30b for driving the high-pressure EGR valve 11a.
The low-pressure EGR device 31 includes a low-pressure EGR passage 31a connecting a position of the exhaust passage 21 downstream of the DPF 29 with a position of the intake passage 20 upstream of the compressor 24, a low-pressure EGR valve 11d for adjusting a flow rate of low-pressure EGR gas through the low-pressure EGR passage 31a, a low-pressure EGR valve actuator 31b for driving the low-pressure EGR valve 11d, and a low-pressure EGR cooler 11c for cooling the low-pressure EGR gas.
The engine 9 and the intake-and-exhaust system configured as above are controlled by a powertrain control module (PCM) 8. The PCM 8 is comprised of a CPU, at least one memory, an interface, etc.
As illustrated in
The PCM 8 determines states of the engine 9, the intake-and-exhaust system and the like by performing a variety of operations based on the detection signals of the sensors, and outputs control signals to the direct injectors 9m and the actuators of the various valves (intake shutter valve actuator 38, high-pressure EGR valve actuator 30b, low-pressure EGR valve actuator 31b) according to the determination result.
Next, a control performed by the PCM 8 is described with reference to the flowchart of
First, the PCM 8 reads the detection values of the various sensors (S31).
Subsequently, the PCM 8 calculates an engine speed based on the rotational angle detected by the crank angle sensor 34, and sets a target torque based on the engine speed and the accelerator opening detected by the accelerator opening sensor 35 (S32).
Next, the PCM 8 sets a required injection amount of fuel based on the engine speed and the target torque (S33).
Then, the PCM 8 selects a fuel injection pattern according to the required injection amount and the engine speed, from a plurality of fuel injection patterns stored in the memory beforehand (S34).
Subsequently, the PCM 8 sets a fuel pressure to be supplied to the direct injectors 9m, based on the required injection amount and the engine speed (S35).
Next, the PCM 8 sets a target oxygen concentration based on the required injection amount and the engine speed (S36). The target oxygen concentration is a target value of an oxygen concentration of the intake mixture immediately before flowing into the cylinders.
Then, the PCM 8 sets a target intake temperature based on the required injection amount and the engine speed (S37). The target intake temperature is a target value of a temperature of the intake mixture immediately before flowing into the cylinders.
Subsequently, the PCM 8 selects an EGR control mode according to the required injection amount and the engine speed, from a plurality of EGR control modes stored in the memory beforehand (S38). The EGR control mode is respectively selected for the high-pressure and low-pressure EGR devices 30 and 31.
Next, the PCM 8 sets state amounts (high-pressure EGR amount, low-pressure EGR amount, and turbocharging pressure) for achieving the target oxygen concentration and the target intake temperature (S39).
Then, the PCM 8 reads restriction ranges of the respective state amounts from the memory (S40). The restriction ranges are ranges which the state amounts need to meet (remain within), respectively, so that the engine 9 and the intake-and-exhaust system can suitably operate, and the restriction ranges are stored in the memory beforehand.
Subsequently, the PCM 8 determines whether the state amounts set at S39 are within the restriction ranges, respectively (S41).
If the state amounts are determined to be within the restriction ranges, respectively (S41: YES), the control proceeds to S43, where the PCM 8 sets control amounts of the direct injectors 9m, the intake shutter valve actuator 38, the high-pressure EGR valve actuator 30b, and the low-pressure EGR valve actuator 31b based on the state amounts set at S39, respectively.
Next, the PCM 8 controls the direct injectors 9m, the intake shutter valve actuator 38, the high-pressure EGR valve actuator 30b, and the low-pressure EGR valve actuator 31b based on the set control amounts, respectively (S44).
At S41, if any of the state amounts is determined to be out of the corresponding restriction range, the PCM 8 corrects the state amount to the corresponding restriction range (S42). For example, the PCM 8 corrects the state amount to a restriction value closest to the state amount set at S39 within the restriction range. After S42, the PCM 8 controls the direct injectors 9m, the intake shutter valve actuator 38, the high-pressure EGR valve actuator 30b, and the low-pressure EGR valve actuator 31b based on the corrected state amount (S44).
Hereinafter, the cooling system of the engine 9 according to this embodiment of the present invention is described.
As illustrated in
The first flow path 2 passes through the cylinder head 9b of the engine 9. The first flow path 2 has a branch point P1 toward the second flow path 3 at a position downstream of the cylinder head 9b. The first flow path 2 has a first auxiliary flow path 2a (path (1)) at a position downstream of the branch point P1. The first auxiliary flow path 2a passes through the high-pressure EGR valve 11a and the intake shutter valve 11b.
The second flow path 3 passes through auxiliary machinery such as components 11a-11f of the engine 9. The second flow path 3 has a branch point P2 at a position downstream of the branch point P1. The second flow path 3 has a second auxiliary flow path 3a (path (2)) and a third auxiliary flow path 3b (path (4)), both connected with the branch point P2. The second and third auxiliary flow paths 3a and 3b are connected in parallel with each other at the branch point P2.
The second auxiliary flow path 3a passes through the low-pressure EGR valve 11d, the low-pressure EGR cooler 11c, and a heater core 11e.
The third auxiliary flow path 3b passes through a radiator 11f.
The third flow path 4 (path (3)) passes through the cylinder block 9a of the engine 9, an oil cooler 11g, and an automatic transmission fluid (ATF) cooler 11h.
The coolant pump 5 is a turbopump and structured such that an impeller thereof is indirectly coupled to the crankshaft 9e of the engine 9. An input port 5a of the coolant pump 5 is connected with a downstream end of the first auxiliary flow path 2a, a downstream end of the second auxiliary flow path 3a, a downstream end of the third auxiliary flow path 3b, and a downstream end of the third flow path 4, via the flow rate control valve 6. An output port 5b of the coolant pump 5 is connected with an upstream end of the first flow path 2 and an upstream end of the third flow path 4.
The coolant pump 5 sucks, via the input port 5a, the coolant within the first to third auxiliary flow paths 2a, 3a, and 3b and the third flow path 4 by pumping in accordance with the rotation of the impeller using a part of engine torque, and discharges the coolant to the first and third flow paths 2 and 4, via the output port 5b. The coolant sucked into the coolant pump 5 is mixed inside the coolant pump 5 before being discharged.
The flow rate control valve 6 is a single rotary valve. The flow rate control valve 6 has a cylindrical casing, a cylindrical valve body rotatably contained inside the casing, and an actuator for rotating the valve body in a single direction. The actuator rotates the valve body based on the control signals (drive voltage) inputted from the PCM 8. Four input ports and four output ports are formed in a side face of the casing. The four input ports are connected with the downstream ends of the first to third auxiliary flow paths 2a, 3a, and 3b and the third coolant flow path 4, respectively. The four output ports are connected with the input port 5a of the coolant pump 5.
Notched portions are formed in the side face of the valve body. Communication areas S formed between the notched portions and the output ports of the casing are individually set for the first to third auxiliary flow paths 2a, 3a, and 3b and the third flow path 4. In the following description, the communication area S for the first auxiliary flow path 2a is referred to as “the communication area S2a,” the communication area S for the second auxiliary flow path 3a is referred to as “the communication area S3a,” the communication area S for the third auxiliary flow path 3b is referred to as “the communication area S3b,” and the communication area S for the third flow path 4 is referred to as “the communication area S4.”
The communication area S2a is stable at a small area near zero regardless of a rotational angle of the valve body (see
On the other hand, the communication areas S3a, S3b, and S4 vary according to the rotational angle of the valve body (see
In other words, the flow rate of the coolant through the second auxiliary flow path 3a is changed according to the variation of the communication area S3a (hereinafter, referred to as “the opening of the flow rate control valve 6 with respect to the second auxiliary flow path 3a”).
Further, the flow rate of the coolant through the third auxiliary flow path 3b is changed according to the variation of the communication area S3b (hereinafter, referred to as “the opening of the flow rate control valve 6 with respect to the third auxiliary flow path 3b”).
Further, the flow rate of the coolant through the third flow path 4 is changed according to the variation of the communication area S4 (hereinafter, referred to as “the opening of the flow rate control valve 6 with respect to the third flow path 4”).
The coolant temperature sensor 7 detects the temperature of the coolant at a position of the first flow path 2, near the cylinder head 9b. The information of the temperature detected by the coolant temperature sensor 7 is transmitted to the PCM 8.
The PCM 8 has a valve control function to control the openings of the flow rate control valve 6 based on the temperature detected by the coolant temperature sensor 7.
Hereinafter, a control of the cooling system by the PCM 8 is described with reference to the flowchart of
Note that, in the following description, the control is started while the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b and the third flow path 4 are zero (closed).
First, the PCM 8 receives a temperature T of the coolant near the cylinder head 9b from the coolant temperature sensor 7 (S51).
Next, the PCM 8 determines whether the received temperature T is below a first temperature threshold T1 (S52). Here, the first temperature threshold T1 is below a temperature at which the engine 9 transitions from a cold state into a warmed-up state after the cold start (e.g., substantially 80° C.), in other words, a temperature while the engine warms up (before being completely warmed up), for example 50° C. (see
If the temperature T is determined to be below the first temperature threshold T1 (S52: YES), at S53, the PCM 8 maintains the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b at zero (see A0 in
If the temperature T is determined to be the first temperature threshold T1 or higher (S52: NO), at S54, the PCM 8 determines whether the temperature T is below a second temperature threshold T2 (e.g., 80° C., see
If the temperature T is determined to be below the second temperature threshold T2 (S54: YES), the PCM 8 increases the opening of the flow rate control valve 6 with respect to the second auxiliary flow path 3a to cancel the flow rate restriction of the coolant in the first flow path 2 (S55). Then, the control returns to S51.
Here, the control performed at S55 is described in detail with reference to the flowchart of
Thus, a small amount of coolant starts to flow into the second auxiliary flow path 3a, and the coolant flowed through the second auxiliary flow path 3a flows into the first flow path 2 via the coolant pump 5. In other words, the flow rate of the coolant flowing through the upstream flow path 2b of the first flow path 2 is the sum of the flow rate of the coolant flowing through the first auxiliary flow path 2a (path (1)) and the flow rate of the coolant flowing through the second auxiliary flow path 3a (path (2)), which means the flow rate increases compared to that at S53 (see A3 in
Then, the PCM 8 determines whether the temperature T detected by the coolant temperature sensor 7 is the same or above a third temperature threshold T3 (e.g., 75° C., see
If the temperature T is determined to be the same or above the third temperature threshold T3 (S62: YES), at S63, the PCM 8 adjusts the opening of the flow rate control valve 6 with respect to the second auxiliary flow path 3a to reach the first target opening for the warmed-up state (see A4 in
Returning to
If the temperature T is determined to be below the fourth temperature threshold T4 (S56: YES), the PCM 8 increases the opening of the flow rate control valve 6 with respect to the third flow path 4 (S57). Then, the control returns to S51.
Here, the control performed at S57 is described in detail with reference to the flowchart of
Then, the PCM 8 determines whether the temperature T detected by the coolant temperature sensor 7 is the same or above a fifth temperature threshold T5 (e.g., 85° C., see
If the temperature T is determined to be the same or above the fifth temperature threshold T5 (S62: YES), at S63, the PCM 8 adjusts the opening of the flow rate control valve 6 with respect to the third flow path 4 to reach the second target opening (see A8 in
Returning to
Here, the control performed at S58 is described in detail with reference to the flowchart of
Thus, the flow rate of the coolant flowing through the upstream flow path 2b of the first flow path 2 increases compared to that at S55 (see A11 in
Then, the PCM 8 determines whether the temperature T detected by the coolant temperature sensor 7 is the same or above a sixth temperature threshold T6 (e.g., 100° C., see
If the temperature T is determined to be the same or above the sixth temperature threshold T6 (S62: YES), at S63, the PCM 8 adjusts the opening of the flow rate control valve 6 with respect to the third auxiliary flow path 3b to reach the third target opening for the warmed-up state (see A12 in
In this regard, as illustrated in
As described above, according to this embodiment, when the temperature of the coolant flowing through the cylinder head 9b is below the first temperature threshold T1, since the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b are adjusted to zero, the flow rate of the coolant flowing through the cylinder head 9b is restricted and the warming up of the engine 9 is stimulated.
When the temperature of the coolant flowing through the cylinder head 9b is the first temperature threshold T1 or higher, since the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b are increased to the predetermined target openings in the stepwise fashion, respectively, the flow rate restriction of the coolant flowing through the cylinder head 9b is gradually canceled and the temperature decrease (overcooling) of the cylinder head 9b can be suppressed.
In other words, when the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b are zero, the coolant within the second and third auxiliary flow paths 3a and 3b does not flow. Therefore, the coolant warmed up by the heat of the engine 9 after the cold start does not flow into the second and third auxiliary flow paths 3a and 3b, and the temperatures of the coolant within the second and third auxiliary flow paths 3a and 3b are comparatively low. When the opening of the flow rate control valve 6 with respect to the second auxiliary flow path 3a is increased (the flow rate control valve 6 is opened) in such a state, the coolant starts to flow through the second auxiliary flow paths 3a, and the comparatively low-temperature coolant within the second auxiliary flow path 3a flows into the first flow path 2. Further, when the opening of the flow rate control valve 6 with respect to the third auxiliary flow path 3b is increased (the flow rate control valve 6 is opened) in such a state, the coolant starts to flow through the third auxiliary flow path 3b, and the comparatively low-temperature coolant within the third auxiliary flow path 3b flows into the first flow path 2. However, since the openings of the flow rate control valve 6 are increased in the stepwise fashion, the flow rate restriction of the coolant flowing through the cylinder head 9b is gradually canceled and the amount of comparatively low-temperature coolant flowing into the cylinder head 9b is gradually increased. Therefore, the overcooling of the cylinder head 9b is suppressed and the sufficient ignitability of the engine 9 after the cold start can be maintained.
Since the opening of the flow rate control valve 6 with respect to the first auxiliary flow path 2a is constantly maintained at a predetermined small opening around zero, a small amount of coolant constantly flows into the first auxiliary flow path 2a. Therefore, by disposing the auxiliary machinery which requires constant cooling by the coolant (e.g., the high-pressure EGR valve 11a, the intake shutter valve 11b) at the first auxiliary flow path 2a, the overheating of the auxiliary machinery can be prevented.
Since the flow rate control valve 6 is opened to be maintained at the predetermined openings below the respective target openings for a while, the low-temperature coolant remaining within the second and third auxiliary flow paths 3a and 3b and the third flow path 4 is gradually supplied to the cylinder head 9b. Therefore, the overcooling of the cylinder head 9b after the cold start can be suppressed and the warming up of the engine 9 can be stimulated.
Although the heat of the coolant within the second auxiliary flow path 3a is taken by the heater core 11e, since the coolant is gradually supplied to the cylinder head 9b, the overcooling of the cylinder head 9b after the cold start can be suppressed.
Although the heat of the coolant within the third auxiliary flow path 3b is released through the radiator 11f, since the coolant is gradually supplied to the cylinder head 9b, the overcooling of the cylinder head 9b after the cold start can be suppressed.
By increasing the opening of the flow rate control valve 6 with respect to the third flow path 4 in the stepwise fashion, the low-temperature coolant remaining within the third flow path 4 when the opening of the flow rate control valve 6 with respect to the third flow path 4 is zero is gradually supplied to the cylinder head 9b and the cylinder block 9a, and therefore, the overcooling of the cylinder head 9b and the cylinder block 9a after the cold start can be suppressed.
Since the rotary valve with which the coolant flow rate becomes higher as the opening thereof is increased is used as the flow rate control valve 6, the flow rate can easily be controlled.
Note that, in this embodiment, the flow rate of the coolant through the first flow path 2 is restricted by adjusting the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b to zero; however, it is not limited to this. For example, the flow rate of the coolant through the first flow path 2 may be restricted by adjusting the openings of the flow rate control valve 6 with respect to the second and third auxiliary flow paths 3a and 3b to predetermined small openings around zero. Moreover, the flow rate of the coolant through the first flow path 2 may be restricted by adjusting the opening of the flow rate control valve 6 with respect to one of the second and third auxiliary flow paths 3a and 3b to zero and the opening of the flow rate control valve 6 with respect to the other one of the second and third auxiliary flow paths 3a and 3b to the predetermined small opening around zero.
In this embodiment, in the second, third, and fourth flowing states, the openings of the flow rate control valve 6 are increased to the respective predetermined target openings for the warmed-up state in the two steps; however, it is not limited to this. For example, the openings of the flow rate control valve 6 may be increased to the target openings in three or more steps.
In this embodiment, the openings of the flow rate control valve 6 are increased to the respective predetermined target openings for the warmed-up state in the stepwise fashion; however, it is not limited to this. For example, the openings of the flow rate control valve 6 may be gradually and continuously increased to the target openings.
It should be understood that the embodiments herein are illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalence of such metes and bounds thereof, are therefore intended to be embraced by the claims.
Number | Date | Country | Kind |
---|---|---|---|
2014-195504 | Sep 2014 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5809944 | Aoki | Sep 1998 | A |
6164248 | Lehmann | Dec 2000 | A |
6539899 | Piccirilli | Apr 2003 | B1 |
6745995 | Hu | Jun 2004 | B2 |
7984700 | Chanfreau | Jul 2011 | B2 |
8347831 | Vacca | Jan 2013 | B2 |
9518503 | Tsuchiya | Dec 2016 | B2 |
9523307 | Lee | Dec 2016 | B2 |
20040154671 | Martins | Aug 2004 | A1 |
20050034688 | Lelkes | Feb 2005 | A1 |
20080295785 | Harris | Dec 2008 | A1 |
20080295791 | Holler | Dec 2008 | A1 |
20100282190 | Stoermer | Nov 2010 | A1 |
20130047940 | Quix | Feb 2013 | A1 |
20140007824 | Hayashi | Jan 2014 | A1 |
20140026829 | Tobergte | Jan 2014 | A1 |
20140069522 | Kuze | Mar 2014 | A1 |
20140326010 | Kawakami | Nov 2014 | A1 |
20150122359 | Tsuchiya | May 2015 | A1 |
Number | Date | Country |
---|---|---|
H06280564 | Oct 1994 | JP |
2007205197 | Aug 2007 | JP |
2013224643 | Oct 2013 | JP |
2014001646 | Jan 2014 | JP |
Number | Date | Country | |
---|---|---|---|
20160090896 A1 | Mar 2016 | US |