Information
-
Patent Grant
-
6390031
-
Patent Number
6,390,031
-
Date Filed
Monday, January 24, 200024 years ago
-
Date Issued
Tuesday, May 21, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Argenbright; Tony M.
- Harris; Katrina B.
Agents
- Harness, Dickey & Pierce, PLC
-
CPC
-
US Classifications
Field of Search
US
- 123 411
- 123 4144
- 123 4112
-
International Classifications
-
Abstract
A flow rate ratio of a radiator flow rate to a bypass flow rate is determined from pump water temperature, bypass water temperature and radiator water temperature. The relation between the flow rate ratio and a valve opening degree of a flow control valve is predetermined as a map. The valve opening degree is determined from the flow rate ratio and the map. Accordingly, the cooling water temperature at an inlet of a pump is accurately controlled without detecting the flow rate of the cooling water.
Description
CROSS-REFERENCE TO RELATED APPLICATION
This application relates to Japanese Patent Application No. Hei. 10-214493 filed Jul. 29, 1998, the entire contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a cooling apparatus for a liquid-cooled internal combustion engine, such as a water-cooled engine, and it is preferably applicable to an internal combustion engine of a vehicle.
2. Description of Related Art
It is necessary to keep the engine cooling water temperature appropriate in order to drive the engine efficiently.
One type of known cooling apparatus for an engine is disclosed in JP-A-63-268912. The cooling apparatus disclosed in JP-A-63-268912 controls the engine cooling water temperature based on a wall surface temperature of the cylinder block of the engine.
In order to appropriately control the engine cooling water temperature at a cooling water inlet of an engine, the inventors of the present invention tried to develop a cooling apparatus having a flow control valve, at a connection between a radiator outlet side and a bypass passage which bypasses the radiator, which controls a flow rate of a radiator and a flow rate of the bypass passage. Further, the inventors tried to feedback control the valve opening degree of the flow control valve based on the cooling water temperature at a cooling water inlet side of the engine (cooling water inlet side of a pump). However, it was difficult to accurately control the cooling water temperature at the cooling water inlet side of the engine (hereinafter referred to as “the inlet temperature”) because of the following reason.
The inlet temperature is determined based on the temperature and the flow rate of the cooling water flowing out from the radiator and the temperature and the flow rate of the cooling water flowing out from the bypass passage. On the other hand, the inventors' experimental model controls the valve opening degree based on only the temperature, regardless of the flow rate.
Accordingly, the change of the flow rate caused by the change of the valve opening amount is not reflected to the control of the flow control valve, and the control accuracy of the inlet temperature is compromised.
To solve this problem, it is possible to detect the flow rates of the cooling water flowing out from the radiator and the cooling water passed through the bypass passage, and to add the detected flow rates to the control parameters. However, it is practically difficult to place a flow rate detector, sensor and the line in the engine room because of the mounting space and the cost thereof.
SUMMARY OF THE INVENTION
The present invention is made in light of the above-mentioned problem, and it is an object of the present invention to provide a cooling apparatus which improves the control accuracy of the inlet temperature without detecting the flow rate of the cooling water.
According to a cooling apparatus of the present invention, an opening degree of a flow control; valve is controlled based on a first temperature (Tp) of the coolant discharged from an outlet of the flow control valve, a second temperature (Tb) of the coolant flowing through a bypass passage, and a third temperature (Tr) of the coolant flowing out from a radiator.
Accordingly, the cooling water temperature at the inlet of the engine is accurately controlled since the flow control valve is controlled by parameters including the flow rate without detecting the flow rate of the cooling water.
BRIEF DESCRIPTION OF THE DRAWINGS
Other features and advantages of the present invention will be appreciated, as well as methods of operation and the function of the related parts, from a study of the following detailed description, the appended claims, and the drawings, all of which form a part of this application. In the drawings:
FIG. 1
is a schematic illustration showing a cooling apparatus for a liquid-cooled internal combustion engine according to a preferred embodiment of the present invention;
FIG. 2A
is a perspective side view showing an integration of a flow control valve and a pump according to the embodiment of the present invention;
FIG. 2B
is a plan view showing the integration of the flow control valve and the pump according to the embodiment of the present invention;
FIG. 3A
is a partially sectional view taken on the line IIIA—IIIA in
FIG. 2A
according to the embodiment of the present invention;
FIG. 3B
is a part of a sectional view taken on the line IIIB—IIIB in
FIG. 3A
according to the embodiment of the present invention;
FIG. 4
is a flowchart showing operations of the cooling apparatus according to the embodiment of the present invention;
FIG. 5
is a control map for the pump according to the embodiment of the present invention;
FIG. 6
is a control map for a blower according to the embodiment of the present invention;
FIG. 7
is a graph showing a relation between the valve opening degree θ and the ratio of the flow rate Vrb according to the embodiment of the present invention;
FIG. 8A
is a graph showing a relation between the engine load and the water temperature at the inlet of the pump (the inlet temperature) according to the embodiment of the present invention;
FIG. 8B
is a graph showing a relation between the engine load and the valve opening degree according to the embodiment of the present invention;
FIG. 8C
is a graph showing a relation between the engine load and the electric power consumption of the pump according to the embodiment of the present invention;
FIG. 8D
is a graph showing a relation between the engine load and the electric power consumption of the blower according to the embodiment of the present invention; and
FIG. 8E
is a graph showing a relation between the engine load and the vehicle speed and the intake pressure according to the embodiment of the present invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENT
A cooling apparatus for a liquid-cooled internal combustion engine of the present invention applied to a water-cooled engine of a vehicle is shown in
FIGS. 1
to
8
as an embodiment of the present invention.
In
FIG. 1
, a radiator
200
cools cooling water (coolant) which circulates in the water-cooled engine
100
. The cooling water circulates through the radiator
200
via a radiator passage
210
.
A part of the cooling water flowing out from the engine
100
can be introduced to an outlet side of the radiator
200
at the radiator passage
210
by bypassing the radiator
200
via a bypass passage
300
.
A rotary-type flow control valve
400
is provided at a junction
220
between the bypass passage
300
and the radiator passage
210
to control the flow rate of the cooling water passing through the radiator passage
210
(hereinafter referred to as “the radiator flow rate Vr”) and the flow rate of the cooling water passing through the bypass passage
300
(hereinafter referred to as “the bypass flow rate Vb”).
An electric pump
500
for circulating the cooling water which is operated independently from the engine
100
is provided at a downstream side of the flow control valve
400
in respect of the water flow direction.
As shown in
FIGS. 2A and 2B
, the flow control valve
400
and the pump
500
are integrated together via a pump housing
510
and a valve housing
410
. The valve housing
410
and the pump housing
510
are made of resin.
As shown in
FIGS. 2A
to
3
B, a cylindrically-shaped rotary valve
420
having an opening at one end thereof (shaped like a cup) is rotatably housed in the valve housing
410
. The valve
420
is rotated around its rotary shaft by an actuator
430
having a servo motor
432
and a speed reducing mechanism comprising several gears
431
.
As shown in
FIG. 3A
, a first valve port
421
and a second valve port
422
, having the identical diameter to each other to communicate the inside with the outside of a cylindrical side surface
420
a,
are formed on the cylindrical side surface
420
a
of the valve
420
. The valve port
421
is deviated from the valve port
422
by about 90°.
A radiator port (radiator side inlet)
411
communicating with the radiator passage
210
and a bypass port (bypass side inlet)
412
communicating with the bypass passage
300
are formed on a part of the valve housing
410
which corresponds to the cylindrical side surface
420
a.
Further, a pump port (outlet)
413
for communicating the suction side of the pump
500
with a cylindrical inner portion
420
b
of the valve
420
is formed on a part of the valve housing
410
which corresponds to an axial end of the rotary shaft of the valve
420
.
A packing
440
seals a gap between the cylindrical side surface
420
a
and the inner wall of the valve housing
410
to prevent the cooling water flowing into the valve housing
410
via the radiator port
411
and the bypass port
412
from bypassing the cylindrical inner portion
420
and flowing to the pump port
413
.
As shown in
FIG. 2A
, a potentiometer
424
is provided on a rotary shaft
423
to detect a rotary angle of the valve
420
, that is a valve opening degree of the flow control valve
400
. Detected signals at the potentiometer
424
are input to ECU
600
.
Electronic control unit (ECU)
600
controls the flow control valve
400
and the pump
500
. Detected signals from a pressure sensor
610
, a first, second and third water temperature sensors
621
,
622
and
623
and a rotary sensor
624
are input to ECU
600
. The pressure sensor
610
detects the manifold air pressure of the engine
100
. The first through third water temperature sensors
621
to
623
detect the cooling water temperature. The rotary sensor
624
detects the engine speed of the engine
100
. ECU
600
controls the flow control valve
400
, the pump
500
and the blower
230
based on these detected signals.
The first water temperature sensor
621
detects a temperature of the cooling water flowing to the pump
500
at a side of the pump port
413
(hereinafter referred to as “the pump water temperature Tp”).
The second water temperature sensor
622
detects a temperature of the cooling water passing through the bypass passage
300
at a side of the bypass port
412
, that is a temperature of the cooling water flowing out from the engine
100
(hereinafter referred to as “the bypass water temperature Tb”).
The third water temperature sensor
623
detects a temperature of the cooling water flowing out from the radiator
200
at a side of the radiator port
413
(hereinafter referred to as “the radiator water temperature Tr”).
The operations of the embodiment will now be described according to a flowchart shown in FIG.
4
.
When the engine
100
starts after turning on an ignition switch (not shown) of the vehicle, the detected signals of the respective sensors
610
,
621
,
622
,
623
and
624
are input to ECU
600
in step S
100
.
In step S
110
, engine load is determined from the engine speed and the manifold air pressure of the engine
100
, and a basic flow rate (rotation speed of the pump
500
) of the cooling water which circulates in the engine
100
and a target temperature of the cooling water which flows in the engine
100
(hereinafter referred to as “the target water temperature Tmap”) are determined from a map not shown.
The target water temperature Tmap is determined such that the water temperature under smaller engine load becomes higher than the water temperature under the greater engine load.
In step S
120
, it is determined whether the pump water temperature Tp is within a certain range including the target water temperature Tmap as a reference point. Specifically, it is determined whether the pump water temperature Tp is within the range between (Tmap−2° C.) and (Tmap+2° C.).
When the pump water temperature Tp is within the certain range, the current valve opening degree of the flow control valve
400
is maintained as it is in step S
130
, and returns to step S
100
.
When the pump water temperature Tp is out of the certain range, the step goes to step S
140
to determine the valve opening degree to be changed from the current opening degree according to the maps shown in
FIGS. 5 and 6
, the flow rate to be changed from the current flow rate (the basic cooling water flow rate), and the blown air amount to be changed from the current blown air amount, based on the temperature difference ΔT (=Tmap−Tp). The valve opening degree, the cooling water flow rate and the blown air amount are determined such that the electric power consumption of the pump
500
and the blower
230
is minimized.
In
FIG. 5
, the rotation speed of the pump
500
increases as the duty of the pump
500
increases. In
FIG. 6
, the rotation speed of the blower
230
increases as the duty of the blower
230
increases. The duty of the pump
500
and the duty of the blower
230
are determined based on the engine load such that the electric power consumption of the pump
500
and the blower
230
is minimized.
In step S
150
, control signals are output to change the operational conditions of the flow control valve
400
, pump
500
and blower
230
. The flow control valve
400
is feedback controlled by repeating steps S
100
through S
150
.
The pump water temperature Tp is determined by the mixture of the cooling water passing through the bypass passage
300
and the cooling water passing through the radiator
200
. Therefore, the detection of the radiator flow rate Vr and the bypass flow rate Vb is necessary as well as the detection of the radiator water temperature Tr and the bypass water temperature Tb in order to match the pump water temperature Tp with the target water temperature Tmap accurately.
However, as described in the above, it is very difficult to measure the flow rate of the cooling water circulating in the cooling apparatus accurately.
According to the embodiment of the present invention, the radiator flow rate Vr and the bypass flow rate Vb, that is the valve opening degree, are determined based on the pump water temperature Tp, the radiator water temperature Tr and the bypass water temperature Tb as described as follows.
Since the pump water temperature Tp is determined by the mixture of the cooling water passing through the bypass passage
300
and the cooling water passing through the radiator
200
, the pump water temperature Tp is represented by the following equation 1.
Tp=
(
Tr·Vr+Tb·Vb
)/(
Vr+Vb
) [Equation 1]
A ratio of the flow rate Vrb is defined by the following equation 2
Vrb=Vr/Vb
[Equation 2]
Accordingly, the equation 1 is converted to the following equation 3.
Tp=
(
Tb+Tr·Vrb
)/(1+
Vrb
) [Equation 3]
Further, the equation 3 is converted to the following equation 4.
Vrb=
(
Tb−Tp
)/(
Tp−Tr
) [Equation 4]
The valve opening degree θ is determined as a function of Vrb as shown in FIG.
7
. Thus, the valve opening degree is univocally determined from Vrb. It is to be noted that the relation between the valve opening degree θ and the flow rate ratio Vrb shown in
FIG. 7
is derived from experimental data.
It is apparent from the equation 4, the flow rate ratio Vrb is calculated from the pump water temperature Tp, radiator water temperature Tr and the bypass water temperature Tb.
If the pump water temperature Tp in the equation 4 is substituted by the target water temperature Tmap, a target flow rate ratio Vrb is determined by equation 5 as follows.
Vrb=
(
Tb−Tmap
)/(
Tmap−Tr
) [Equation 5]
In this specification, the flow rate ratio Vrb determined by the equation 4 is called “the actual flow rate ratio Vrb”, and the flow rate ratio Vrb determined by the equation 5 is called “the target flow rate ratio Vrb”.
Accordingly, the target valve opening degree is determined by the target flow rate ratio Vrb and
FIG. 7
, and the actual valve opening degree is determined by the actual flow rate ratio Vrb and FIG.
7
. The valve opening degree to be changed from the current valve opening degree (changing amount of the valve opening degree) shown in the map in
FIG. 5
is determined from the difference between the target flow rate ratio Vrb and the actual flow rate ratio Vrb.
According to the embodiment of the present invention, the valve opening degree is accurately determined from the pump water temperature Tp, the radiator water temperature Tr and the bypass water temperature Tb, without measuring the actual cooling water flow rate.
Although the pump water temperature Tp is determined according to only the conditions of the cooling water passing through the bypass passage
300
and the cooling water passing through the radiator
200
, there are time lags among the water temperature detection at the first through third water temperature sensors
621
through
623
. Therefore, there may be a difference between the actual temperature and the detected temperature. Thus, it is desirable to place the first through third water temperature sensors
621
through
623
as close as possible.
When the engine load increases and the target water temperature Tmap decreases, the valve opening degree is changed and the radiator flow rate Vr increases. However, changing amount of the heat radiation performance of the radiator
100
against the changing amount of the radiator flow rate Vr (change ratio of the heat radiation performance) becomes smaller as the radiator flow rate Vr (flow speed in the radiator
200
) becomes larger.
Even if the radiator flow rate Vr is increased in order to reduce the pump water temperature Tp, the heat radiation performance is not increased compared to the increased amount of the radiator flow rate Vr. Accordingly, the ratio of the cooling performance to the pump work of the pump
500
(the electric power consumption of the pump
500
) necessary for circulating the cooling water to the radiator
200
is reduced, and unnecessary pump work increases.
According to the embodiment of the present invention, however, the blown air amount of the blower
230
is controlled based on the engine load. Thus, the heat radiation performance of the radiator
200
is increased when the blown air amount is increased according to the increase of the engine load. Accordingly, increase of the unnecessary pump work is prevented.
In
FIG. 8A
, the solid line represents the pump water temperature Tp when the blown air amount is increased according to the increase of the engine load, and the dotted line represents the pump water temperature Tp when the blown air amount is not increased according to the increase of the engine load.
It is apparent from
FIGS. 8A and 8B
that the electric power consumption of the pump water temperature Tp and the pump
500
is reduced when the blown air amount is increased according to the increase of the engine load even though the valve opening degree and the radiator flow rate Vr are smaller than those in the case when the blown air amount is not increased according to the increase of the engine load.
In general, flow speed of the traveling wind passing through the radiator
200
when a vehicle runs is comparably small, such as about 10% of the flow speed of the traveling wind. Accordingly, it is difficult to cool the cooling water only by the travelling wind when the vehicle speed is low and the engine load is large, such as at the slope to climb.
According to the embodiment of the present invention, however, the blown air amount at the blower
230
increases when the engine load is large. Accordingly, the cooling water temperature (the pump water temperature Tp) is certainly reduced when the engine load is large. Thus, the cooling water temperature is properly controlled according to the engine load.
In the embodiment of the present invention, three water temperature sensors
621
,
622
and
623
are used to detect three kinds of water temperature, that is the pump water temperature Tp, the radiator water temperature Tr and the bypass water temperature Tb. However, it is possible to eliminate the second water temperature sensor
622
for detecting the bypass water temperature Tb, and the bypass water temperature Tb may be estimated from the pump water temperature Tp and the radiator water temperature Tr instead. One example of the estimation method for the ratio of the flow rate Vrb when the second water temperature sensor
622
is eliminated will now be described.
The bypass water temperature Tb is derived from the equation 4 as shown in the equation 6.
Tb=Tp+
(
Tp−Tr
)·
Vrb
[Equation 6]
Since the ratio of the flow rate Vrb is univocally determined from the valve opening degree θ as shown in
FIG. 7
, the bypass water temperature Tb is estimated from a valve opening degree determined from a detected value of the potentiometer
424
.
Since the maps shown in
FIGS. 5 and 6
are determined for the atmospheric temperature of 25° C. in the above embodiment, it may be preferable to add a correction step between step S
140
and step S
150
for correcting the determined values determined in step S
140
.
Although the present invention has been described in connection with the preferred embodiments thereof with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art. Such changes and modifications are to be understood as being included within the scope of the present invention as defined in the appended claims.
Claims
- 1. A cooling apparatus for a liquid-cooled internal combustion engine using a coolant, comprising:a radiator for cooling the coolant circulating between the liquid-cooled internal combustion engine and said radiator; a bypass passage for introducing the flowing from the liquid-cooled internal combustion engine to an outlet side of said radiator directly to bypass said radiator; a flow control valve having a bypass side inlet through which the coolant having passed through said bypass passage flows in, and a radiator side inlet through which the coolant having passed through said radiator flows in, and an outlet for discharging the coolant to the engine, for controlling a flow rate of the coolant passing through said bypass passage and the coolant passing through said radiator by changing an opening degree of said flow control valve; and control means for controlling the opening degree of said flow control valve, wherein said control means calculates an actual flow rate based on a first temperature of the coolant flowing out of said flow control valve, a second temperature of the coolant flowing through said bypass passage, and a third temperature of the coolant flowing out of said radiator; said control means calculates a target flow rate based on a target coolant temperature, the second temperature of the coolant flowing through said bypass passage, and the third temperature of the coolant flowing out of said radiator; and said control means controls the opening degree of said flow control valve based on the actual flow rate and the target flow rate.
- 2. A cooling apparatus according to claim 1, wherein said opening degree of said flow control valve is feedback controlled based on said first, second and third temperatures such that said first temperature conforms with the target coolant temperature determined based on an engine load of the engine.
- 3. A cooling apparatus according to claim 2, wherein;said cooling apparatus includes a blower for generating air flow passing through said radiator; and blown air amount of said blower is controlled based on the engine load of the engine.
- 4. A cooling apparatus according to claim 2, wherein;said cooling apparatus includes a pump which is driven independently of the engine for circulating the coolant; and discharging flow rate of said pump is controlled based on the engine load of the engine.
- 5. A cooling apparatus according to claim 1, wherein;said cooling apparatus includes a blower for generating air flow passing through said radiator; and blown air amount of said blower is controlled based on an engine load of the engine.
- 6. A cooling apparatus according to claim 5, wherein;said cooling apparatus includes a pump which is driven independently of the engine for circulating the coolant; and discharging flow rate of said pump is controlled based on the engine load of the engine.
- 7. A cooling apparatus according to claim 6, wherein the opening degree of said flow control valve is controlled in such a manner that electric consumption of said pump and blower is minimized.
- 8. A cooling apparatus according to claim 5, wherein the blown air amount of said blower is controlled in a stepwise manner based on the engine load of the engine.
- 9. A cooling apparatus according to claim 1, wherein;said cooling apparatus includes a pump which is driven independently of the engine for circulating the coolant; and discharging flow rate of said pump is controlled based on an engine load of the engine.
- 10. A cooling apparatus for a liquid-cooled internal combustion engine using a coolant, comprising:a radiator for cooling the coolant circulating between the liquid-cooled internal combustion engine and said radiator; a bypass passage for introducing the flowing from the liquid-cooled internal combustion engine to an outlet side of said radiator directly to bypass said radiator; a flow control valve for controlling a flow rate of the coolant passing through said bypass passage and the coolant passing through said radiator by changing an opening degree of said flow control valve; and control means for controlling the opening degree of said flow control valve; wherein: said control means calculates an actual flow rate based on a first temperature of the coolant flowing out of said flow control valve, a second temperature of the coolant flowing flowing through said bypass passage, and a third temperature of the coolant flowing out of said radiator; the first temperature is determined by the mixture of the coolant flowing through said bypass passage and the coolant flowing through said radiator; said control means calculates a target flow rate based on a target coolant temperature, the second temperature of the coolant flowing through said bypass passage, and the third temperature of the coolant flowing out of said radiator; and said control means controls the opening degreee of said flow control valve based on the actual flow rate and the target flow rate.
US Referenced Citations (4)
Number |
Name |
Date |
Kind |
4545333 |
Nagumo et al. |
Oct 1985 |
A |
5390632 |
Ikebe et al. |
Feb 1995 |
A |
6101987 |
Saur et al. |
Aug 2000 |
A |
6109219 |
Sano |
Aug 2000 |
A |