The present invention relates to a variable valve timing apparatus and a control method therefor. In particular, the invention relates to a variable valve timing apparatus that varies the timing at which a valve is opened/closed by a variation amount according to an operation amount of an actuator, and a control method therefor.
VVT (Variable Valve Timing) has conventionally been known that changes the phase (crank angle) in (at) which an intake valve or an exhaust valve is opened/closed, according to an operating condition. Generally, the VVT changes the phase by rotating, relative to a sprocket or the like, a camshaft that causes the intake valve or exhaust valve to open/close. The camshaft is rotated by such an actuator as hydraulic or electric motor. Particularly, in the case where the electric motor is used to rotate the camshaft, the torque for rotating the camshaft is difficult to obtain, as compared with the case where the camshaft is hydraulically rotated. Therefore, in the case where the electric motor is used to rotate the camshaft, the rotational speed of the output shaft of the electric motor is reduced by a speed reducer mechanism or the like, thereby rotating the camshaft. In this case, the degree of phase shift is restricted by the speed reducer mechanism.
Japanese Patent Laying-Open No. 2004-150397 discloses a valve timing adjustment device with a great degree of freedom of phase shift. The valve timing adjustment device disclosed in Japanese Patent Laying-Open No. 2004-150397 is provided to a transmission system for transmitting drive torque from a drive shaft of an internal combustion engine to a driven shaft for opening and closing at least one of an air intake valve and an exhaust valve, for adjusting the timing at which at least one of the air intake valve and the exhaust valve opens and closes. The valve timing adjustment device includes: a first rotator rotating around a rotation centerline by the drive torque from the drive shaft; a second rotator rotating around the rotation centerline together with the rotation of the first rotor and in the same direction as the first rotor so as to make the driven shaft rotate synchronously, wherein the second rotor is capable of rotating relative to the first rotor; and a control device having a control member and varying the radial distance of the control member from the rotation centerline. The first rotor defines a first hole forming a first track that extends so as to vary its radial distance from the rotation centerline. The first hole makes contact with the control member that passes through the first track, with the contact between the first hole and the control member occurring at two sides of the first hole toward which the first rotor rotates. The second rotor defines a second hole forming a second track extending so as to vary its radial distance from the rotation centerline and making contact with the control member that passes through the second track, with the contact between the second hole and the control member occurring at two sides of the second hole toward which the second rotor rotates. The first track and the second track slant toward each other along the rotational direction of the first rotor and the rotational direction of the second rotor. In this valve timing device, in the case where the electric motor generates no torque, the phase is maintained.
According to the valve timing adjustment device disclosed in this publication, the first hole of the first rotor forms a first track that extends so as to vary its radial distance from the rotation centerline and makes contact with the control member that passes through the first track, with the contact between the first hole and the control member occurring at two sides of the first hole toward which the first rotor rotates. Furthermore, the second hole of the second rotor forms a second track extending so as to vary its radial distance from the rotation centerline and makes contact with the control member that passes through the second track, with the contact between the second hole and the control member occurring at two sides of the second hole toward which the second rotor rotates. Here, the first track and the second track slant toward each other along the rotational direction of the first rotor and the rotational direction of the second rotor. Therefore, when the control device acts to change the control member's radial distance from the rotation centerline, the control member presses against at least one of the first hole and the second hole, whereby the control member passes through both the first track and the second track, and thus the second rotor is caused to rotate relative to the first rotor. In the valve timing adjustment device which operates in the forgoing manner, the degree of phase shift of the second rotor with respect to the first rotor is dependent upon the length of the first track and the second track and the degree to which the first track and the second track slant toward each other. By extending the first track and the second track such that they vary their radial distances from the rotation centerline, relative freedom is achieved in determining the length and the mutual slant of the tracks. In turn, this increases freedom in setting the degree of phase shift of the second rotor with respect to the first rotor, and therefore, the degree of phase shift of the driven shaft with respect to the drive shaft.
Here, as in the valve timing adjustment device disclosed in Japanese Patent Laying-Open No. 2004-150397, even in the case where the phase can be varied by the electric motor, the phase cannot always be controlled accurately in all the operating states. However, Japanese Patent Laying-Open No. 2004-150397 does not consider the case where the phase cannot be controlled accurately, so that the phase may be varied to be different from the target phase when the phase is to be controlled.
An object of the present invention is to provide a variable valve timing apparatus and the like, which can restrain deterioration in accuracy of the phase.
A variable valve timing apparatus in accordance with an aspect of the present invention changes an opening/closing timing of at least any one of an intake valve and an exhaust valve of an engine. The variable valve timing apparatus includes: an actuator operating the variable valve timing apparatus; a change mechanism changing the opening/closing timing at a variation amount according to an operation amount of the actuator; and an operation unit. The operation unit controls the opening/closing timing by controlling the actuator, and stops control of the opening/closing timing if a rotational speed of the engine is equal to or lower than a predetermined rotational speed.
According to the present invention, the opening/closing timing is changed at a variation amount according to an operation amount of the actuator. Here, if the engine speed is low and the rotational speed of the camshaft is low, the phase cannot be detected accurately in the cam position sensor that is provided opposing to the cam angle sensor plate provided to the camshaft, for example, to detect the phase based on variation in magnetic flux passing through a coil part as the camshaft rotates. If the phase is controlled in the state where the actual phase is erroneously detected, the phase may become unsuitable for the operating state. Then, if the rotational speed of the engine is equal to or lower than a predetermined rotational speed, the control of the opening/closing timing is stopped. Accordingly, control of the phase can be restrained in a state where the actual phase is erroneously detected. As a result, it is possible to provide a variable valve timing apparatus that can restrain deterioration in accuracy of the phase.
Preferably, the operation unit controls the opening/closing timing by controlling power supply to the actuator, and, if a rotational speed of the engine is equal to or lower than the predetermined rotational speed, stops control of the opening/closing timing by stopping power supply to the actuator.
According to the present invention, the opening/closing timing is controlled by controlling power supply to the actuator. If the rotational speed of the engine is equal to or lower than a predetermined rotational speed, the power supply to the actuator is stopped. Accordingly, control of the phase can be restrained in a state where the actual phase is erroneously detected. As a result, deterioration in accuracy of the phase can be prevented.
Preferably, the change mechanism changes the opening/closing timing at a first variation amount with respect to an operation amount of the actuator in a case where the opening/closing timing is in a first region, and changes the opening/closing timing at a second variation amount larger than the first variation amount with respect to an operation amount of the actuator in a case where the opening/closing timing is in a second region different from the first region. Both in a case where the opening/closing timing is in the first region and in a case where the opening/closing timing is in the second region, if a rotational speed of the engine is equal to or lower than the predetermined rotational speed, the operation unit stops control of the opening/closing timing by stopping power supply to the actuator.
According to the present invention, in the case where the opening/closing timing is in the first region, the opening/closing timing is changed at a first variation amount with respect to an operation amount of the actuator. In the case where the opening/closing timing is in the second region, the opening/closing timing is changed at a second variation amount larger than the first variation amount with respect to an operation amount of the actuator. Accordingly, the opening/closing timing can be varied widely in the second region. On the other hand, in the first region, the variation amount of the opening/closing timing is small, in other words, the reduction gear ratio is high. Therefore, even in the state where the actuator generates no torque, it is less likely that the actuator is driven by the torque acting on the camshaft as the engine operates, for example. Therefore, the opening/closing timing is less likely to be varied. Accordingly, in the first region, if the rotational speed of the engine is equal to or lower than a predetermined rotational speed, the power supply to the actuator is stopped thereby to maintain the opening/closing timing. Thus, deterioration in accuracy of the phase can be prevented. On the other hand, in the second region, in the state where the actuator generates no torque, the torque that acts on the camshaft as the engine operates, for example, drives the actuator thereby possibly varying the opening/closing timing. However, if the rotational speed of the engine is equal to or lower than a predetermined rotational speed, the power supply to the actuator is stopped. Accordingly, control of the phase can be restrained in the state where the actual phase is erroneously detected. Therefore, erroneous control of the phase can be prevented. As a result, deterioration in accuracy of the phase can be prevented.
With reference to the drawings, an embodiment of the present invention is hereinafter described. In the following description, like components are denoted by like reference characters. They are also named identically and function identically. Therefore, a detailed description thereof is not repeated.
Referring to
An engine 1000 is a V-type 8-cylinder engine having an “A” bank 1010 and a “B” bank 1012 each including a group of four cylinders. Here, any engine other than the V8 engine may be used.
Into engine 1000, air is sucked from an air cleaner 1020. The quantity of sucked air is adjusted by a throttle valve 1030. Throttle valve 1030 is an electronic throttle valve driven by a motor.
The air is supplied through an intake manifold 1032 into a cylinder 1040. The air is mixed with fuel in cylinder 1040 (combustion chamber). Into cylinder 1040, the fuel is directly injected from an injector 1050. In other words, injection holes of injector 1050 are provided within cylinder 1040.
The fuel is injected in the intake stroke. The fuel injection timing is not limited to the intake stroke. Further, in the present embodiment, engine 1000 is described as a direct-injection engine having injection holes of injector 1050 that are disposed within cylinder 1040. However, in addition to direct-injection injector 1050, a port injector may be provided. Moreover, only the port injector may be provided.
The air-fuel mixture in cylinder 1040 is ignited by a spark plug 1060 and accordingly burned. The air-fuel mixture after burned, namely exhaust gas, is cleaned by a three-way catalyst 1070 and thereafter discharged to the outside of the vehicle. The air-fuel mixture is burned to press down a piston 1080 and thereby rotate a crankshaft 1090.
At the top of cylinder 1040, an intake valve 1100 and an exhaust valve 1110 are provided. Intake valve 1100 is driven by an intake camshaft 1120. Exhaust valve 1110 is driven by an exhaust camshaft 1130. Intake camshaft 1120 and exhaust camshaft 1130 are coupled by such parts as a chain and gears to be rotated at the same rotational speed.
Intake valve 1100 has its phase (opening/closing timing) controlled by an intake VVT mechanism 2000 provided to intake camshaft 1120. Exhaust valve 1110 has its phase (opening/closing timing) controlled by an exhaust VVT mechanism 3000 provided to exhaust camshaft 1130.
In the present embodiment, intake camshaft 1120 and exhaust camshaft 1130 are rotated by the VVT mechanisms to control respective phases of intake valve 1100 and exhaust valve 1110. Here, the phase control method is not limited to the aforementioned one.
Intake VVT mechanism 2000 is operated by an electric motor 2060 (not shown in
Exhaust VVT mechanism 3000 is hydraulically operated. Here, intake VVT mechanism 2000 may be hydraulically operated while exhaust VVT mechanism 3000 may be operated by an electric motor.
To ECU 4000, signals indicating the rotational speed and the crank angle of crankshaft 1090 are input from a crank angle sensor 5000. Further, to ECU 4000, signals indicating respective phases of intake camshaft 1120 and exhaust camshaft 1130 (the signal indicating the respective phases of intake valve 1100 and exhaust valve 1110) (phase: the camshaft position in the rotational direction) are input from a cam position sensor 5010.
Cam position sensor 5010 is an electromagnetic pickup sensor provided opposing to a cam angle sensor plate (not shown) provided at the camshaft for detecting a phase based on variation in magnetic flux passing through a coil part as the camshaft rotates.
Furthermore, to ECU 4000, a signal indicating the water temperature (coolant temperature) of engine 1000 from a coolant temperature sensor 5020 as well as a signal indicating the quantity of intake air (quantity of air taken or sucked into engine 1000) of engine 1000 from an airflow meter 5030 are input.
Based on these signals input from the sensors as well as a map and a program stored in a memory (not shown), ECU 4000 controls the throttle opening position, the ignition timing, the fuel injection timing, the quantity of injected fuel, the phase of intake valve 1100 and the phase of exhaust valve 1110 for example, so that engine 1000 is operated in a desired operating state.
In the present embodiment, ECU 4000 determines the phase of intake valve 1100 based on the map as shown in
In the map shown in
In the following, a further description is given of intake VVT mechanism 2000. Here, exhaust VVT mechanism 3000 may be configured identically to intake VVT mechanism 2000 as described below.
As shown in
Sprocket 2010 is coupled via a chain or the like to crankshaft 1090. The rotational speed of sprocket 2010 is half the rotational speed of crankshaft 1090. Intake camshaft 1120 is provided concentrically with the rotational axis of sprocket 2010 and rotatably relative to sprocket 2010.
Cam plate 2020 is coupled to intake camshaft 1120 with a pin (1) 2070. Cam plate 2020 rotates, on the inside of sprocket 2010, together with intake camshaft 1120. Here, cam plate 2020 and intake camshaft 1120 may be integrated into one unit.
Link mechanism 2030 is comprised of an arm (1) 2031 and an arm (2) 2032. As shown in
As shown in
Arm (2) 2032 is supported so that the arm can swing about a pin (3) 2074 and with respect to arm (1) 2031. Further, arm (2) 2032 is supported so that the arm can swing about a pin (4) 2076 and with respect to cam plate 2020.
A pair of link mechanisms 2030 causes intake camshaft 1120 to rotate relative to sprocket 2010 and thereby changes the phase of intake valve 1100. Thus, even if one of the paired link mechanisms 2030 is broken as a result of any damage or the like, the other link mechanism can be used to change the phase of intake valve 1100.
Referring back to
Each control pin 2034 slides in guide groove 2042 of guide plate 2040 to shift in the radial direction. The radial shift of each control pin 2034 causes intake camshaft 1120 to rotate relative to sprocket 2010.
As shown in
As control pin 2034 is shifted further in the radial direction from the axial center of guide plate 2040, the phase of intake valve 1100 is retarded to a greater extent. In other words, the variation amount of the phase has a value corresponding to the operation amount of link mechanism 2030 generated by the radial shift of control pin 2034. Alternatively, the phase of intake valve 1100 may be advanced to a greater extent as control pin 2034 is shifted further in the radial direction from the axial center of guide plate 2040.
As shown in
Referring back to
Speed reducer 2050 is comprised of an outer teeth gear 2052 and an inner teeth gear 2054. Outer teeth gear 2052 is fixed with respect to sprocket 2010 so that the gear rotates together with sprocket 2010.
Inner teeth gear 2054 has a plurality of protruded portions 2056 thereon that are received in depressed portions 2044 of guide plate 2040. Inner teeth gear 2054 is supported rotatably about an eccentric axis 2066 of a coupling 2062 formed eccentrically with respect to an axial center 2064 of an output shaft of electric motor 2060.
When electric motor 2060 causes coupling 2062 to rotate about axial center 2064 and relative to outer teeth gear 2052, accordingly inner teeth gear 2054 as a whole revolves about axial center 2064 while inner teeth gear 2054 rotates about eccentric axis 2066. The rotational motion of inner teeth gear 2054 causes guide plate 2040 to rotate relative to sprocket 2010 and thus the phase of intake valve 1100 is changed.
The phase of intake valve 1100 is changed by reduction of the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 (operation amount of electric motor 2060) by speed reducer 2050, guide plate 2040 and link mechanism 2030. Here, the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 may be increased to change the phase of intake valve 1100.
As shown in
In the case where the phase of intake valve 1100 is in a first region from the most retarded angle to CA (1), the reduction gear ratio of intake VVT mechanism 2000 as a whole is R (1). In the case where the phase of intake valve 1100 is in a second region from CA (2) (CA (2) is advanced with respect to CA (1)) to the most advanced angle, the reduction gear ratio of intake VVT mechanism 2000 as a whole is R (2) (R (1)>R (2)).
In the case where the phase of intake valve 1100 is in a third region from CA (1) to CA (2), the reduction gear ratio of intake VVT mechanism 2000 as a whole changes at a predetermined rate of change ((R (2)−R (1))/(CA (2)−CA (1)).
The function of intake VVT mechanism 2000 of the variable valve timing apparatus will be described below.
In the case where the phase of intake valve 1100 (intake camshaft 1120) is to be advanced, electric motor 2060 is operated to rotate guide plate 2040 relative to sprocket 2010, thereby advancing the phase of intake valve 1100 as shown in
In the case where the phase of intake valve 1100 is in the first region between the most retarded angle and CA (1), the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is reduced at reduction gear ratio R (1) to advance the phase of intake valve 1100.
In the case where the phase of intake valve 1100 is in the second region between CA (2) and the most advanced angle, the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is reduced at reduction gear ratio R (2) to advance the phase of intake valve 1100.
In the case where the phase of intake valve 1100 is to be retarded, the output shaft of electric motor 2060 is rotated relative to sprocket 2010 in the direction opposite to the direction in the case where the phase thereof is to be advanced. In the case where the phase is to be retarded, similarly to the case where the phase is to be advanced, when the phase of intake valve 1100 is in the first region between the most retarded angle and CA (1), the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is reduced at reduction gear ratio R (1) to retard the phase. Further, when the phase of intake valve 1100 is in the second region between CA (2) and the most advanced angle, the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is reduced at reduction gear ratio R (2) to retard the phase.
Accordingly, as long as the direction of the relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is the same, the phase of intake valve 1100 can be advanced or retarded for both of the first region between the most retarded angle and CA (1) and the second region between CA (2) and the most advanced angle. Here, for the second region between CA (2) and the most advanced angle, the phase can be more advanced or more retarded. Thus, the phase can be changed over a wide range.
Further, since the reduction gear ratio is high for the first region between the most retarded angle and CA (1), a large torque is necessary for rotating the output shaft of electric motor 2060 by a torque acting on intake camshaft 1120 as engine 1000 operates. Therefore, in the case where electric motor 2060 is stopped for example, even if electric motor 2060 generates no torque, rotation can be restrained of the output shaft of electric motor 2060 caused by the torque acting on intake camshaft 1120. Therefore, a change of the actual phase from a phase determined under control can be restrained.
In the chase where the phase of intake valve 1100 is in the third region between CA (1) and CA (2), the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is reduced at a reduction gear ratio that changes at a predetermined rate of change, which may result in advance or retard in phase of intake valve 1100.
Accordingly, in the case where the phase changes from the first region to the second region or from the second region to the first region, the variation amount of the phase with respect to the rotational speed of relative rotation between the output shaft of electric motor 2060 and sprocket 2010 can be increased or decreased gradually. In this way, a sudden stepwise change of the variation amount of the phase can be restrained to thereby restrain a sudden change in phase. Accordingly, the capability to control the phase can be improved.
In addition, as described above, in the map for use to determine the phase of intake valve 1100, the phase in the first region between the most retarded angle and CA (1) and the phase in the second region between CA (2) and the most advanced angle are defined. On the other hand, the phase in the third region between CA (1) and CA (2) is not defined.
Thus, it can be restrained that intake VVT mechanism 2000 is controlled such that the phase falls in the third region where the reduction gear ratio varies. Therefore, it can be restrained that the phase is controlled in the region where the variation amount of the phase is hardly predicted because of the varied reduction gear ratio. As a result, deterioration in accuracy of the phase can be prevented.
Referring to
At the step (abbreviated as S hereinafter) 100, ECU 4000 detects the rotational speed of crank shaft 1090, namely engine speed NE based on the signal transmitted from crank angle sensor 5000.
At S102, ECU 4000 determines whether or not engine speed NE is equal to or lower than threshold value NE (0). If engine speed NE is equal to or lower than threshold value NE (0) (YES at S102), the process goes to S104. If not (NO at S102), the process goes to S200. At S104, ECU 4000 stops the power supply to electric motor 2060. Here, whether the phase of intake valve 1100 is in the first region or in the second region, the power supply to electric motor 2060 is stopped. At S200, ECU 4000 uses the map shown in
At S202, ECU 4000 operates electric motor 2060 so that the phase of intake valve 1100 becomes the target phase.
At S204, ECU 4000 detects the phase of intake camshaft 1120, namely the phase of intake valve 1100 based on the signal transmitted from cam position sensor 5010.
At S206, ECU 4000 determines whether or not the difference between the phase of intake valve 1100 and the target phase becomes equal to or lower than the threshold value. When the difference between the phase of intake valve 1100 and the target phase becomes equal to or lower than the threshold value (YES at S206), the process goes to S208. If not (NO at S206), the process returns to S202.
At S208, ECU 4000 determines whether or not the phase of intake valve 1100 is in the first region between the most retarded angle and CA (1). If the phase of intake valve 1100 is in the first region (YES at S208), the process goes to S210. If not (NO at S208), the process goes to S212.
At S210, ECU 4000 stops the power supply to electric motor 2060. At S212, ECU 4000 continues the power supply to electric motor 2060 so as to prevent the relative rotation between the output shaft of electric motor 2060 and sprocket 2010. In other words, in the state where the power supply to electric motor 2060 is continued, the phase variation of intake valve 1100 is stopped.
The operation of the variable valve timing apparatus in accordance with the present embodiment will be described based on the structure and flowchart as described above.
During the operation of engine 1000, engine speed NE is detected based on the signal transmitted from crank angle sensor 5000 (S100). If engine speed NE is low and engine speed NE is equal to or lower than threshold value NE (0) (YES at S102), it can be said that the rotational speed of intake camshaft 1120 is low. In this case, the variation in magnetic flux in the coil part of cam position sensor 5010 is not enough, and thus it can be said that cam position sensor 5010 is in the state where it cannot detect the rotational speed of intake camshaft 1120 accurately, namely in the state where it cannot detect the phase of intake valve 1100.
Even if the phase is controlled in such a state, the phase is hardly realized as controlled. On the contrary, the phase may become unsuitable for the operating state. Then, in order to stop control of the phase, the power supply to electric motor 2060 is stopped (S104).
If the power supply to electric motor 2060 is stopped in the case where the phase of intake valve 1100 is in the first region, the phase at the time of stopping the power supply is maintained, even in the state where electric motor generates no torque, because of high reduction gear ratio.
If the power supply to electric motor 2060 is stopped in the case where the phase of intake valve 1100 is in the second region, the output shaft of electric motor 2060 is rotated relative to sprocket 2010 thereby possibly varying the phase, because of not so high reduction gear ratio. However, the phase may sometimes be maintained.
On the other hand, if engine speed NE is higher than threshold value NE (0) (NO at S102), the variation in magnetic flux in the coil part of cam position sensor 5010 is enough to bring about a state of readiness to detect the phase of intake valve 1100 accurately. In this case, using the map shown in
When the difference between the phase of intake valve 1100 and the target phase becomes equal to or lower than the threshold value (YES at S206), it is determined whether or not the phase of intake valve 1100 is in the first region between the most retarded angle and CA (1) (S208).
In the first region (YES at S208), as mentioned above, the reduction gear ratio is high. Therefore, even in the state where electric motor 2060 generates no torque, the output shaft of electric motor 2060 is less likely to be rotated by the torque acting on intake camshaft 1120. In other words, although the output shaft of electric motor 2060 is rotated (is forced to rotate) at the same rotational speed as sprocket 2010, the relative rotation between the output shaft of electric motor 2060 and sprocket 2010 is less likely to be caused and the phase of intake valve 1100 is less likely to be varied.
Then, the power supply to electric motor 2060 is stopped (S210). Accordingly, the phase of intake valve 1100 can be maintained in the state where the power supply to electric motor 2060 is stopped. Therefore, fuel economy can ultimately be enhanced.
On the other hand, outside of the first region (NO at S208), the reduction gear ratio is not high. Therefore, in the state where electric motor 2060 generates no torque, the output shaft of electric motor 2060 is rotated relative to sprocket 2010 by the torque acting on intake camshaft 1120, so that the phase of intake valve 1100 may not be maintained. Accordingly, the power supply to electric motor 2060 is continued so as to generate such torque that does not cause relative rotation between the output shaft of electric motor 2060 and sprocket 2010 (S212).
As described above, in the variable valve timing apparatus in accordance with the present embodiment, in the case where engine speed NE is lower than threshold value NE (0), the power supply to the electric motor is stopped thereby to stop control of the phase. Accordingly, control of the phase can be restrained in a state where the phase cannot be detected accurately. Therefore, deterioration in accuracy of the phase can be prevented.
It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
Number | Date | Country | Kind |
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2006-045316 | Feb 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/052075 | 1/31/2007 | WO | 00 | 8/20/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/099745 | 9/7/2007 | WO | A |
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Number | Date | Country | |
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20100162980 A1 | Jul 2010 | US |