The present invention relates to a marine gear device which transmits a rotary power of a main engine mounted to a marine vessel to a propeller.
Conventionally, a marine gear device (a speed reducing and reversing device) for a marine vessel such as a pleasure boat is provided with a forward and reverse travel switching clutch which can switch a rotary power of the engine to a forward travel output and a reverse travel output (refer to Patent Document 1). In the marine vessel with this kind of marine gear device, a shifter of the forward and reverse travel switching clutch is connected to a forward and reverse travel lever provided in a control seat of a ship body by a long wire cable. Further, the forward and reverse travel switching clutch is switched and actuated by transmitting an operation force of the forward and reverse travel lever to the shifter via the wire cable, thereby switching a traveling direction of the ship body to the forward travel and the reverse travel.
Patent Document 1: Japanese Unexamined Patent Publication No. 7-17486
However, in the prior art, since the manual operation force of the forward and reverse travel lever is transmitted to the shifter via the long wire cable, there has been a problem that a great force is necessary for manually operating the forward and reverse travel lever, an operation resistance (an operational feeling) is heavy and an operation load of a ship operator is great.
In the existing marine gear device employing a clutch switching structure by means of a wire cable, there are extremely a lot of requests of reducing the operation force which is required for the manual operation of the forward and reverse travel lever. As a countermeasure for reducing the manual operation force, there can be thought that the forward and reverse travel switching clutch is switched and actuated, for example, by using an electric actuator. However, since it is not originally assumed that the wire cable is replaced with the electric actuator in the existing marine gear device, it is understood that a lot of man hour is necessary for an embedding work of the electric actuator. Further, in the case that the electric actuator breaks down, for example, due to water immersion, it is impossible to switch and actuate the forward and reverse travel switching clutch, and it is understood that a fail-safe problem exists.
A technical object of the present invention is to provide a marine gear device to which an improvement is applied after making a study of the actual condition as mentioned above.
According to the invention of a first aspect, there is provided a marine gear device transmitting a rotary power of a main engine mounted to a marine vessel to a propeller, comprising:
an input shaft to which the rotary power of the main engine is input;
a forward and reverse travel switching mechanism which switches the rotary power of the input shaft to a forward travel output, a neutral output or a reverse travel output;
an operating part which actuates the forward and reverse travel switching mechanism to a forward travel state, a neutral state or a reverse travel state on the basis of a rotary motion; and
an electric actuator which rotates the operating part in correspondence to an operation of a forward and reverse travel operation tool,
wherein the operating part is provided with a self-return member which forcibly rotates the operating part when any electric power is not supplied to the electric actuator, and returns the forward and reverse travel switching mechanism to the neutral state.
According to the invention of a second aspect, there is provided the marine gear device described in the first aspect, further comprising:
an actuation detecting member which detects an actuation state of the electric actuator; and
a controller which drives the electric actuator in response to the operation of the forward and reverse travel operation tool,
wherein the controller discriminates on the basis of a detection information of the actuation detecting member whether the forward and reverse travel switching mechanism is in the forward travel state, the neutral state or the reverse travel state.
According to the invention of a third aspect, there is provided the marine gear device described in the first aspect or the second aspect, wherein the operating part or the electric actuator is provided with an emergency manual operation tool for manually operating the operating part independently from the electric actuator.
According to the invention of a fourth aspect, there is provided the marine gear device described in the first aspect, wherein the electric actuator is an electric direct acting actuator having a rod body which moves forward and backward in connection with the operation of the forward and reverse travel operation tool, and the electric direct acting actuator and the operating part are connected via a conversion mechanism which converts a forward and backward motion of the rod body into a rotating motion of the operating part.
According to the invention of a fifth aspect, there is provided the marine gear device described in the fourth aspect, wherein a center line in a forward and backward moving direction of the rod body is biased so as not to intersect with a center of rotation of the operating part as seen from a direction along the center of rotation of the operating part.
According to the invention of a sixth aspect, there is provided the marine gear device described in the fourth aspect or the fifth aspect, wherein the conversion mechanism is constructed by loosely fitting to a loosely fitting hole which is formed in any one of the rod body and the operating part, a pivotally supporting pin which is provided in the other.
According to the invention of a seventh aspect, there is provided the marine gear device described in the fourth aspect or the fifth aspect, wherein the electric direct acting actuator is supported to a gear case which accommodates the forward and reverse travel switching mechanism, and an arrangement and posture of the electric direct acting actuator in relation to the gear case is changeable so as not to prevent the forward and backward movement of the rod body.
According to the invention of an eighth aspect, there is provided the marine gear device described in the first aspect, further comprising an output shaft which transmits an output of the forward and reverse travel switching mechanism to the propeller,
wherein the electric actuator is arranged in a gear case itself which accommodates the input shaft, the output shaft and the forward and reverse travel switching mechanism or in the vicinity thereof, and a main body of the electric actuator is positioned above an axial line of the output shaft.
According to the invention of a ninth aspect, there is provided the marine gear device described in the eighth aspect, wherein an upper end of the main body of the electric actuator is set to a height position which is lower than the highest end of the gear case.
According to the invention of the first aspect, the marine gear device transmitting the rotary power of the main engine mounted to the marine vessel to the propeller is provided with the input shaft to which the rotary power of the main engine is input, the forward and reverse travel switching mechanism which switches the rotary power of the input shaft to the forward travel output, the neutral output or the reverse travel output, the operating part which actuates the forward and reverse travel switching mechanism to the forward travel state, the neutral state or the reverse travel state on the basis of the rotary motion, and the electric actuator which rotates the operating part in correspondence to the operation of the forward and reverse travel operation tool, the operating part is provided with the self-return member which forcibly rotates the operating part when any electric power is not supplied to the electric actuator, and returns the forward and reverse travel switching mechanism to the neutral state. When the electric actuator breaks down or the power supply is turned off, the forward and reverse travel switching mechanism is not set to the forward travel or the reverse travel state. Therefore, it is possible to do away with the risk that the marine vessel actuates unexpectedly despite the ship operator's intention after restoring from the breakdown. It is preferable for the fail-safe.
According to the invention of the second aspect, the marine gear device is provided with the actuation detecting member which detects the actuation state of the electric actuator, and the controller which drives the electric actuator in response to the operation of the forward and reverse travel operation tool, and the controller discriminates on the basis of the detection information of the actuation detecting member whether the forward and reverse travel switching mechanism is in the forward travel state, the neutral state or the reverse travel state. Therefore, it is possible to accurately comprehend the actuation state of the electric actuator and further the state of the forward and reverse travel switching mechanism on the basis of the detection information of the actuation detecting member. It is possible to secure reliability in relation to the drive control of the electric actuator.
According to the invention of the third aspect, the operating part or the electric actuator is provided with the emergency manual operation tool for manually operating the operating part independently from the electric actuator. Therefore, even in the case that any electric system trouble, for example, the abnormality in the electric actuator is generated, it is possible to execute a limp home operation (a degeneracy operation) traveling forward and reverse the marine vessel in a state in which the electric actuator is not effective, by manually operating the emergency manual operation tool. Accordingly, options for dealing with the emergency circumstances are increased, and it is further preferable in the light of the fail-safe.
According to the invention of the fourth aspect, the electric actuator is the electric direct acting actuator having the rod body which moves forward and backward in connection with the operation of the forward and reverse travel operation tool, and the electric direct acting actuator and the operating part are connected via the conversion mechanism which converts the forward and backward motion of the rod body into the rotating motion of the operating part. Therefore, it is possible to electrically achieve the switch and actuation of the forward and reverse travel switching mechanism without using the conventional long wire cable. It is possible to securely reduce the operation force which is required for the manual operation of the forward and reverse travel operation tool.
Further, as mentioned above, since the electric direct acting actuator and the operating part are connected via the conversion mechanism which converts the forward and backward motion of the rod body into the rotating motion of the operating part, it is possible to easily replace the wire cable with the electric direct acting actuator later even in the existing marine gear device which includes the wire cable.
According to the invention of the fifth aspect, the center line in the forward and backward moving direction of the rod body is biased so as not to intersect with the center of rotation of the operating part as seen from the direction along the center of rotation of the operating part. Therefore, the rod body (the electric direct acting actuator) and the operating part are connected while avoiding a dead center where the rotating force does not work, in the conversion mechanism, and it is possible to secure a smooth motion conversion.
According to the invention of the sixth aspect, the conversion mechanism is constructed by loosely fitting to the loosely fitting hole which is formed in any one of the rod body and the operating part, the pivotally supporting pin which is provided in the other. Therefore, it is possible to smoothly convert the forward and backward movement of the rod body into the rotary motion of the operating part without generating any complication in the connection between the rod body and the operating part. It is possible to achieve the smooth motion conversion, and further the secure switch and actuation of the forward and reverse travel switching mechanism, in spite of the simple structure constructed by the combination of the loosely fitting hole and the pivotally supporting pin.
According to the invention of the seventh aspect, the electric direct acting actuator is supported to the gear case which accommodates the forward and reverse travel switching mechanism, and the arrangement and posture of the electric direct acting actuator in relation to the gear case is changeable so as not to prevent the forward and backward movement of the rod body. Therefore, it is possible to achieve the smooth motion conversion and further the secure switch and actuation of the forward and reverse travel switching mechanism in spite of the simple structure in this case, in the same manner as the third aspect.
According to the invention of the eighth aspect, the marine gear device is provided with the output shaft which transmits the output of the forward and reverse travel switching mechanism to the propeller, and the electric actuator is arranged in the gear case itself which accommodates the input shaft, the output shaft and the forward and reverse travel switching mechanism or in the vicinity thereof, and the main body of the electric actuator is positioned above the axial line of the output shaft. Therefore, the electric actuator is positioned at the gear case itself or at the comparatively high position in the vicinity of the gear case. Accordingly, it is possible to reduce the risk that the electric actuator breaks down due to the water immersion. The maintenance work of the electric actuator such as an inspection and a repair and replacement can be easily carried out, and it is possible to reduce the load of the maintenance work.
According to the invention of the ninth aspect, the upper end of the main body of the electric actuator is set to the height position which is lower than the highest end of the gear case. Therefore, it is possible to arrange the electric actuator without increasing a vertical height of the gear case while securing the maintenance workability of the electric actuator. Accordingly, it is possible to achieve compactness of the vertical height of the marine gear device.
a) is a schematic side elevational view describing a switching structure of a forward and reverse travel switching clutch;
b) is a schematic plan view describing an attaching structure of a neutral spring;
A description will be given below of embodiments obtained by embodying the present invention with reference to the accompanying drawings. As shown in
A control portion 12 is provided in a rear side of the mast 7. Within the control portion 12, there are provided a steering handle 13 which changes a traveling direction of the ship body 2 to the right and left on the basis of steering, and a forward and reverse travel lever 14 serving as a forward and reverse travel operation tool which switched the traveling direction of the ship body 2 to a forward travel and a reverse travel. A propeller shaft 15 rotating the propeller 5 is axially supported to a back end side of the ship bottom in the ship body 2. The propeller 5 is attached to a protruding end side of the propeller shaft 15.
An inner portion of the ship body 2 is provided with an engine 20 serving as a main engine which is a drive source of the propeller 5, and a marine gear device (a speed reducing and reversing device) 21 which transmits a rotary power of the engine 20 to the propeller 5 via the propeller shaft 15. The propeller 5 is rotated by the rotary power which is transmitted to the propeller shaft 15 from the engine 20 via the marine gear device 21.
As shown in
Although details will be omitted, a flywheel is provided in a protruding end side of an output shaft (a crank shaft) of the engine 20. The input shaft 23 of the marine gear device 21 is connected to the flywheel via a damper joint. Therefore, the rotary power of the engine 20 is input to the input shaft 23 of the marine gear device 21 via the flywheel and the damper joint.
A relay shaft 24 and an output shaft 25 which extend in parallel to the input shaft 23 are axially supported rotatably within the gear case 22 in addition to the input shaft 23 mentioned above. The output shaft 25 protrudes in an opposite direction to the input shaft 23 from the gear case 22. A coupling 26 for connecting the propeller shaft 15 is attached to a protruding end side of the output shaft 25.
The input shaft 23 is integrally provided with a forward travel input gear 31 and a reverse travel input gear 32. Meanwhile, a forward travel gear 33 and a reverse travel gear 34 are axially supported to the output shaft 25 rotatably, the forward travel gear 33 corresponding to the forward travel input gear 31, and the reverse travel gear 34 corresponding to the reverse travel input gear 32. The forward travel input gear 31 constantly engages with the forward travel gear 33. Each of the reverse travel input gear 32 and the reverse travel gear 34 constantly engages with a relay gear 35 which is integrally provided in the relay shaft 24.
In other words, it is possible to transmit the power in a forward rotating direction (a forward travel direction) directly to the output shaft 25 from the input shaft 23 on the basis of the engagement between the forward travel input gear 31 and the forward travel gear 33. Meanwhile, it is possible to transmit the power in a reverse rotating direction (a reverse travel direction) to the output shaft 25 from the input shaft 23 via the relay shaft 24 on the basis of the engagement between the reverse travel input gear 32 and the reverse travel gear 34 via the relay gear 35.
A forward and reverse travel switching clutch 40 is provided between the forward travel gear 33 and the reverse travel gear 34 in the output shaft 25. A cone clutch (a conical clutch) which is an example of a dry type friction clutch is employed as the forward and reverse travel switching clutch 40 according to the first embodiment. The forward and reverse travel switching clutch 40 is spline fitted to the output shaft 25 so as to be relatively non-rotatable and be slidable in an axial direction. The forward travel gear 33 and the reverse travel gear 34 are selectively connected to the output shaft 25 on the basis of an operation of the forward and reverse travel switching clutch 40.
A pair of truncated conical portions 41 and 42 are formed in the forward and reverse travel switching clutch 40, the truncated conical portions 41 and 42 facing to the forward travel gear 33 or the reverse travel gear 34. Further, cone cup portions 37 and 38 are formed in a concave manner in the forward travel gear 33 and the reverse travel gear 34, the cone cup portions 37 and 38 which the corresponding truncated conical portions 41 and 42 are fitted to and friction engage with. When the forward travel side truncated conical portion 41 of the forward and reverse travel switching clutch 40 is fitted to the cone cup portion 37 of the forward travel gear 33, the forward travel gear 33 integrally rotates the forward and reverse travel switching clutch 40, and the output shaft 25 rotates in the forward rotating direction (the forward travel direction). When the reverse travel side truncated conical portion 42 of the forward and reverse travel switching clutch 40 is fitted to the cone cup portion 38 of the reverse travel gear 34, the reverse travel gear 34 integrally rotates the forward and reverse travel switching clutch 40, and the output shaft 25 rotates in the reverse rotating direction (the reverse travel direction).
An outward opening annular groove 43 is formed between both the truncated conical portions 41 and 42 in an outer peripheral surface of the forward and reverse travel switching clutch 40. A leading end side of a shifter 44 is engaged with the annular groove 43, the shifter 44 controlling in a sliding manner the forward and reverse travel switching clutch 40 on the output shaft 25. A base end side of the shifter 44 is attached to a switching shaft 45 which is axially supported to one side wall of the gear case 22 rotatably, in a state in which the base end side is eccentric from an axis of the switching shaft 45. The switching shaft 45 protrudes outward from the one side wall of the gear case 22. A switching lever 46 serving as an operating part is attached to a protruding end side of the switching shaft 45.
The forward and reverse travel switching clutch 40 is selectively slidable to a neutral position shown in
When the forward and reverse travel switching clutch 40 is slid along the output shaft 25 on the basis of the rotating motion of the switching lever 46, the alternatively selected forward travel gear 33 or reverse travel gear 34 is connected to the output shaft 25. In the case that the forward travel gear 33 is selected, the rotary power in the forward rotating direction (the forward travel direction) is directly transmitted to the output shaft 25 from the input shaft 23, and the output shaft 25 and further the propeller 5 of the propeller shaft 15 rotates in the forward rotating direction (the forward travel direction). In the case that the reverse travel gear 34 is selected, the rotary power in the reverse rotating direction (the reverse travel direction) is transmitted to the output shaft 25 from the input shaft 23 via the relay shaft 24, and the output shaft 25 and further the propeller 5 of the propeller shaft 15 rotates in the reverse rotating direction (the reverse travel direction).
As shown in
The electric cylinder 50 is connected in an interlocking manner to the switching lever 46 via a conversion mechanism 53 which converts the forward and backward movement of the rod 52 into a rotating motion of the switching lever 46. As shown in
When the rod 52 of the electric cylinder 50 moves forward and backward, the pivotally supporting pin 54 slidably moves the loosely fitting hole 55 in the switching lever 46 side. As a result, the forward and backward movement of the rod 52 is smoothly converted into the rotating motion of the switching lever 46 without generating any complication in the connection between the rod 52 of the electric cylinder 50 and the switching lever 46. Further, as shown in
As shown in
The neutral springs 56 and 56 pull at each other in opposite directions in a state in which they are respectively loaded between the locking bolt 57 of the switching lever 46 and the support bolt 58 of the attaching bracket 49. As a result, in the case that any power is not supplied to the electric cylinder 50, for example, when the electric cylinder 50 breaks down or the power supply is turned off, the switching lever 46 and further the forward and reverse travel switching clutch 40 are automatically returned to the neutral position (refer to
In this case, a guide block 61 is attached to the leading end side of the rod 52. The loosely fitting hole 55 is formed in the guide block 61, the loosely fitting hole 55 being long in a direction intersecting the longitudinal direction of the rod 52. The pivotally supporting pin 54 is attached to the leading end side of the switching lever 46. Further, the pivotally supporting pin 54 is fitted to the loosely fitting hole 55 of the guide block 61 so as to be prevented from coming off and be slidably movable. The other structures are approximately the same as those of the first embodiment.
In the structure of the first modified example, the pivotally supporting pin 54 in the switching lever 46 side slidably moves along the loosely fitting hole 55 in the rod 52 side when the rod 52 of the electric cylinder 50 moves forward and backward. As a result, the forward and backward movement of the rod 52 is smoothly converted into the rotating motion of the switching lever 46 without generating any complication in the connection between the rod 52 of the electric cylinder 50 and the switching lever 46. In other words, the same operations and effects as those of the first embodiment can be obtained in the structure of the first modified example.
According to the structure of the second modified example, the cylinder main body 51 rotates like a pendulum around the upper end side serving as the supporting point in conjunction with the bending and rotating motion of the rod 52 and the switching lever 46 on the basis of the forward and backward movement of the rod 52. As a result, the forward and backward movement of the rod 52 is smoothly converted into the rotating motion of the switching lever 46 without generating any complication in the connection between the rod 52 of the electric cylinder 50 and the switching lever 46. In other words, the same operations and effects as those of the first embodiment can be obtained in the structure of the second modified example.
As is apparent from the above description and
Further, the electric (the direct acting) actuator 50 and the operating part 46 are connected via the conversion mechanism 53 which converts the forward and backward movement of the rod body 52 into the rotating motion of the operating part 46 as mentioned above. Therefore, even in the existing marine gear device using the wire cable, it is possible to simply replace the wire cable with the electric (the direct acting) actuator 50 by the later attachment.
As is apparent from the above description and
As is apparent from the above description and
As is apparent from the above description and
The controller 70 is structured such as to detect the protruding amount of the rod 52 of the electric cylinder 50 (comprehend the rotating angle (the rotating position) of the switching lever 46) on the basis of the detection information of the rotating angle sensor 73, and discriminate whether the forward and reverse travel switching clutch 40 is in the forward travel state, the neutral state or the reverse travel state. With the structure mentioned above, it is possible to accurately comprehend the actuation state of the electric cylinder 50 and further the state of the forward and reverse travel switching clutch 40 on the basis of the detection information of the rotating angle sensor 73. Therefore, it is possible to secure the reliability of the electric cylinder 50 in relation to the drive control.
It goes without saying that the structure of the function block diagram of the first embodiment can be applied to the first to fifth modified examples mentioned above. Further, the actuation detecting member is not limited to the rotating angle sensor 73, but may employ the forward and reverse travel lever sensor 72 mentioned above, or may employ a rod sensor which directly detects the protruding amount of the rod 52 of the electric cylinder 50. It is possible to employ a lever rotating angle sensor which detects the rotating angle (the rotating position) of the switching lever 46 or the switching shaft 45.
In this case, the switching shaft 45 protrudes outward from one side wall of the gear case 22. A switching shaft spur gear 81 is fixed to the protruding end side of the switching shaft 45 in place of the switching lever 46 serving as the operating part. Meanwhile, a motor main body 84 of the electric switching motor 80 serving as the electric actuator is supported to an outer surface side of the one side wall of the gear case 22. A pinion spur gear 83 is constantly engaged with the switching shaft spur gear 81, the pinion spur gear 83 being firmly fixed to a switching motor shaft 82 which protrudes out of the motor main body 84.
The second embodiment is structured such as to forward and reverse rotate the pinion spur gear 83 of the electric switching motor 80 in correspondence to the operation of the forward and reverse travel lever 14. The switching shaft 45 and further the shifter 44 rotate on the basis of the rotation of the pinion spur gear 83 by the electric switching motor 80. As a result, the forward and reverse travel switching clutch 40 is selectively slid to a neutral position, a forward travel position which connects the forward travel gear 33 to the output shaft 25, and a reverse travel position which connects the reverse travel gear 34 to the output shaft 25. In the second embodiment, the switching shaft 45 (or the switching shaft spur gear 81) corresponds to the operating part.
Even in the case structured as mentioned above, it is possible to electrically achieve the switch and actuation of the forward and reverse travel switching clutch 40 without using the conventional long wire cable. It is possible to securely reduce the operation force which is required for the manual operation of the forward and reverse travel lever 14.
As shown in
As shown in
In any case of employing the first modified example or the second modified example, it is possible to electrically achieve the switch and actuation of the forward and reverse travel switching clutch 40 without using the conventional long wire cable, in the same manner as the second embodiment. Therefore, it is possible to securely reduce the operation force which is required for the manual operation of the forward and reverse travel lever 14. It goes without saying that the structures of the function block diagram according to the first embodiment can be applied even in the second embodiment and the first and second modified examples. In this case, the motor driver 71 drives the electric switching motor 80, and the rotating angle sensor 73 detects the rotating angle of the switching motor shaft 82. The controller 70 comprehends the rotating angle (the rotating position) of the switching shaft 45 on the basis of the detection information of the rotating angle sensor 73, and discriminates whether the forward and reverse travel switching clutch 40 is in the forward travel state, the neutral state or the reverse travel state.
In the seventh modified example, the electric cylinder 50 is provided with an emergency manual operation tool 92 for manually operating the switching lever 46 independently from the electric cylinder 50. In this case, the emergency manual operation tool 92 is provided in the upper end side of the cylinder main body 51. Although details are not shown, a base end side of the emergency manual operation tool 92 is connected to the rod 52 within the cylinder main body 51. The rod 52 moves forward and backward and the switching shaft 45 and further the shifter 44 rotate by manually rotating the emergency manual operation tool 92. As a result, the forward and reverse travel switching clutch 40 is selectively slid to the neutral position, the forward travel position and the reverse travel position.
The emergency manual operation tools 91 and 92 according to the sixth and seventh embodiments are not normally operated, but are operated in the case that an electric system trouble, for example, an abnormality in the electric cylinder 50 is generated, for an emergency avoiding purpose. Even in the case that the electric system trouble is generated, it is possible to execute a limp home operation (a degeneracy operation) traveling forward and reverse the yacht 1 in a state in which the electric cylinder 50 is not effective, by manually operating each of the emergency manual operation tool 91 or 92. Therefore, options for dealing with the emergency circumstances are increased, and this is further preferable in the light of the fail-safe.
As is apparent from the above description and
As is apparent from the above description and
As is apparent from the above description and
In the marine gear devices 21 according to the first embodiment and the modified examples thereof shown in
When these structures are employed, the electric cylinder 50 and the electric switching motor 80 are positioned at the gear case 22 itself or the comparatively high place in the vicinity of the gear case 22. Therefore, it is possible to reduce the risk that the electric cylinder 50 and the electric switching motor 80 break down due to the water immersion. Further, The maintenance work of the electric cylinder 50 and the electric switching motor 80 such as the inspection and the repair and replacement can be easily carried out, and it is possible to reduce the load of the maintenance work. Further, since the upper ends of the cylinder main body 51 and the motor main body 84 are set to the height positions which are lower than the highest end of the gear case 22 by the height H, it is possible to arrange the electric cylinder 50 and the electric switching motor 80 without increasing the vertical height of the gear case 22 while securing the maintenance workability of the electric cylinder 50 and the electric switching motor 80. Therefore, it is possible to reduce the vertical height of the marine gear device 22.
The structure of each of the portions in the present invention is not limited to the illustrated embodiments, but can be variously changed within a range which does not deflect from the scope of the present invention.
Number | Date | Country | Kind |
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2012-208347 | Sep 2012 | JP | national |
2012-208348 | Sep 2012 | JP | national |
2012-208349 | Sep 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/075324 | 9/19/2013 | WO | 00 |