POWER SWITCHING DEVICE FOR VEHICLE
A power switching device for vehicle has at least first and second power switching mechanisms, a shared operating mechanism, and a housing accommodating the power switching mechanisms and the shard operating mechanism, the housing being integrally formed with a boss portion having a waiting mechanism, wherein the waiting mechanism includes drive and driven cylindrical shafts, and a coil spring connecting between the cylindrical shafts, both of the cylindrical shafts and the coil spring are arranged in a same axis, and are supported on an inner peripheral surface of the boss portion through drive and driven side needle roller bearings respectively, the coil spring is arranged inside the cylindrical shafts.
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1. Technical Field of the Invention
The present invention relates to a power switching device for a vehicle arranged on a motive power transmission passage from a driving source to wheels.
2. Description of the Prior Art
A power switching mechanism constituting the power switching device for vehicle includes, for example, a two-wheel-drive/four-wheel-drive switching mechanism, a differential lock mechanism, a speed change gear mechanism, or different kinds of clutch mechanisms. Some of the power switching mechanisms have a waiting mechanism which can temporarily accumulate operative power by means of a coli spring.
One type of the power switching mechanism with the coil spring is to utilize compression and tension of the coil spring in an axis direction thereof, and the other type is to utilize torsion or twist of the coil spring around the axis thereof. Japanese Patent publication No. 2011-121458 discloses a differential lock mechanism having the former waiting mechanism, and Japanese Patent publication No. 2000-118257 shows a differential lock mechanism having the latter waiting mechanism.
The operating arm 205a is connected to an electric actuator 211 so as to transmit operative power for switching. The actuating arm 206a has a shift pin 212 which is connected to a differential lock mechanism 213.
When the operating arm 205a is rotated by the electric actuator 211, the actuating arm 206a is rotated through the coil spring 210, so that the differential lock mechanism 213 is switched between locked condition and unlocked condition by means of the shift pin 212. In case that the differential lock mechanism is switched from lock condition to unlock condition, a drive dog teeth and a driven dog teeth (or recess) are changed from disengaged state to engaged state. However, when end faces of both the dog teeth are abutted each other, the coil spring 210 is distorted or twisted around the axis of the coil spring. As a result, the power switching mechanism will come into waiting condition.
In the structure shown in
Further, in case that only the differential lock mechanism is operated, two switching positions shall be sufficient for switching of the power switching device. However, in case that three or more switching positions are required by adding the other switching device, it will be required to increase torsion angle of the coil spring. But, in case that relative torsion angle between the drive cylindrical shaft 205 and the driven cylindrical shaft 206 is increased, the coil spring is contracted or reduced in a radial direction by the torsion of the coil spring. By the contraction of the coil spring in the radial direction, the coil spring is pressed against the outer peripheral surface of the shared support shaft 201. Therefore, it will become difficult to produce smoothly the waiting action.
SUMMARY OF THE INVENTIONThe present invention is achieved in consideration with the above problem, and an object thereof is, in a power switching device, to increase an area of a surface rotatably supporting a drive cylindrical shaft and a driven cylindrical shaft, thereby suppress contact pressure of the surface, as a result it becomes possible to produce smooth switching operation and smooth waiting action and to increase the torsion angle between the cylindrical shafts.
In order to achieve above the object, a power switching device for vehicle according the present invention comprises at least first and second power switching mechanisms arranged on the way of a driving force transmission passage from a driving source to wheels; a shared operating mechanism to switch both of the first and second power switching mechanisms on and off; the shared operating mechanism having a waiting mechanism; and a housing accommodating the first and second power switching mechanisms and the shard operating mechanism, the housing being integrally formed with a boss portion having the waiting mechanism built-in, wherein the waiting mechanism includes a drive cylindrical shaft located in operation side, a driven cylindrical shaft located in actuation side, and a coil spring connecting the driven cylindrical shaft with the drive cylindrical shaft so as to transmit operating power, both of the drive and driven cylindrical shafts and the coil spring are arranged in a same cylindrical shaft axis, the drive cylindrical shaft is supported on an inner peripheral surface of the boss portion through a drive side needle roller bearing, and the driven cylindrical shaft is supported on the inner peripheral surface of the boss portion through a driven side needle roller bearing, and the coil spring is arranged inside the drive cylindrical shaft and the driven cylindrical shaft.
According to the present invention, outer peripheral surfaces of the drive cylindrical shaft and the driven cylindrical shaft are supported on the inner peripheral surface of the boss portion through the needle roller bearings respectively, so that a surface supporting both the cylindrical shafts increases, thereby suppress contact pressure of the surface, as a result it becomes possible to smoothly-rotate the both cylindrical shafts and smoothly-produce waiting action due to the torsion of the coil spring.
In addition, it becomes possible to increase a diameter of the coil spring without enlarging an inside diameter of the boss portion, thereby increase maximum a torsion angle of the coil spring. As a result, even if a large rotation angle of the driven cylindrical shaft is required (number of the switching positions is increased), the waiting action will be smoothly produced on any position.
The above invention may have the following features.
(a) The drive cylindrical shaft and the driven cylindrical shaft have substantially the same outside diameter, the inner peripheral surface of the boss portion has an uniform inside diameter, and the drive side needle roller bearing and the driven side needle roller bearing are arranged next to each other in the cylindrical shaft axis, and are retained by a shared retainer.
With the above configuration (a), a structure of the waiting mechanism becomes simple, and a work to incorporate the waiting mechanism into the boss portion is improved.
(b) In the power switching device for vehicle including the above configuration (a), one of the drive cylindrical shaft and the driven cylindrical shaft is formed with an arcuate notch about the cylindrical shaft axis, and the other is formed with a projection for engaging with the notch so as to be movable in a circumferential direction, and only when at least one of the first and second switching mechanisms is operated from a disengaged condition of the power to an engaged condition, the projection and the notch are relatively moved in the circumferential direction to compress the coil spring.
With the above configuration (b), in the case that the first switching mechanism or the second switching mechanism is switched, it becomes possible to produce the waiting action only when the switching mechanism is operated to an engagement condition in which the waiting action is required. On the contrary, when the switching mechanism is operated to a disengagement condition, the waiting action is not produced. Thereby, in any case of the engagement action and the disengagement action, the power switching device smoothly acts corresponding to the switching operation.
(c) In the power switching device for vehicle including the above configuration (b), the restricting notch and the restricting projection are located in a position corresponding to a boundary between the drive side needle roller bearing and the driven side needle roller bearing in the cylindrical shaft axis direction, and are opposite to the above boundary from inside in a radial direction of the cylindrical shafts.
With the above configuration (c), it becomes possible to make efficient use of a space between the drive side needle roller bearing and the driven side needle roller bearing, and the waiting mechanism can be made compact.
(d) In the power switching device for vehicle, the first switching mechanism is a two-wheel-drive/four-wheel-drive switching mechanism, and the second switching mechanism is a differential lock mechanism which can lock a differential device.
With the above configuration (d), in the vehicle provided with the two-wheel-drive/four-wheel-drive switching mechanism and the differential lock mechanism, any switching operation, of the two-wheel-drive/four-wheel-drive switching mechanism and the differential lock mechanism, can be performed utilizing the waiting mechanism.
(e) In the power switching device for vehicle including the above configuration (d), the shared shift lever of the shared operating mechanism can be switched among a first position, a second position and a third position, when the shared shift lever is located in the first position, the two-wheel-drive/four-wheel-drive switching mechanism is in a two-wheel-drive condition, and the differential lock mechanism is in an unlocked condition, when the shared operation shift lever is located in the second position, the two-wheel-drive/four-wheel-drive switching mechanism is in a four-wheel-drive condition, and the differential lock mechanism is in the unlocked condition, and when the shared shift lever is located in the third position, the two-wheel-drive/four-wheel-drive switching mechanism is in the four-wheel-drive condition, and the differential lock mechanism is in a locked condition,
The above object, features, and advantages of the present invention will be more apparent from the following description in connection with the accompanying drawings.
The engine 14 has a transmission 15. A propeller shaft 16 for front wheels extending forward and a propeller shaft 17 for rear wheels extending rearward are connected to a power take-off portion 15a at a lower end of the transmission 15. A rear end of the propeller shaft for rear wheels 17 is coupled to right and left rear axles 23 via a final reduction gear for rear wheels 22. A front end of the propeller shaft for front wheels 16 is coupled to right and left front axles 27 via a universal joint 36 and a final reduction gear for front wheels 26 having a differential device for front wheels 25.
The final reduction gear mechanism 30 has an input pinion 34 extending in a front-rear direction and a large-diameter ring gear 35. A rear end of a shaft portion of the input pinion 34 is connected to the universal joint 36 via the two-wheel-drive/four-wheel-drive switching mechanism 31. A rear end of the universal joint 36 is spline-fitted to a front end of the propeller shaft 16 for front wheels. The ring gear 35 is coupled to a differential case 38 of the differential device 25 and is rotated about a front axle axis O1 so as to be integral with the differential case 38.
The differential device 25 has the differential case 38, a support shaft 41 fixed to the differential case 38, a pair of differential gears 42 rotatably supported by the support shaft 41, and a left side gear 44 and a right side gear 45 for engaging with both the differential gears 42. A right front axle 27b is spline-fitted to the right side gear 45, and a left front axle 27a is spline-fitted to the left side gear 44. In the embodiment, the differential lock mechanism 39 is provided between the left front axle 27a and the differential case 38. In other words, the differential lock mechanism 39 directly couples the differential case 38 and the left front axle 27a to bring the differential device 25 into a locked condition.
[Differential Lock Mechanism 39]The differential lock mechanism 39 has inner spline teeth 54 formed on an inner circumferential surface of a boss portion at a left end of the differential case 38, and outer spline teeth 53 formed on an outer circumferential surface of a first shift sleeve 51 movable in a front axle direction. The first shift sleeve 51 is spline-fitted to an outer circumferential surface of a coupling sleeve 50 fixed to a right end of the left front axle 27a so as to be movable in the front axle direction.
A condition of the differential lock mechanism 39 of
As the operating mechanism for moving the first shift sleeve 51 in the front axle direction, a first shift fork 56 for engaging with an outer circumference annular groove of the first shift sleeve 51 and a shift lever 60 having a first guide groove 58 for engaging with a first drive pin 56a of the first shift fork 56 are provided. The first shift fork 56 is supported by a first shift support shaft 61 arranged in parallel with the front axle 27 so as to be movable in a shift axial direction. The shift lever 60 is rotatably supported by a lever support shaft 62 fixed to the reduction gear case 33. The shift lever 60 is also used as the operating mechanism of the two-wheel-drive/four-wheel-drive switching mechanism 31.
In
As the operating mechanism for moving the second shift sleeve 73 in the front-rear direction, a second shift fork 74 for engaging with an outer circumference annular groove of the second shift sleeve 73 is provided. The second shift fork 74 is supported by a second shift support shaft 63 fixed to the reduction gear case 33 and extending in the front-rear direction so as to be movable in the front-rear direction, and a second drive pin 74a of the second shift fork 74 engages with a second guide groove 75 formed at a rear end of the shared shift lever 60.
The second shift sleeve 73 of
The shared shift lever 60 is rotated about the lever support shaft 62 and can be switched between a first position shown in
In
In
In other words, when the shift lever 60 is in the first position of
In addition, three contact type position sensors 77-1, 77-2, and 77-3 are spaced in the circumferential direction so as to be opposite to a rear end face of the shift lever 60. On the other hand, a projection 78 for position detection abuttable onto ends of detection pins 77a-1, 77a-2, and 77a-3 of the three position sensors 77-1, 77-2, and 77-3 is formed on the rear end face of the shift lever 60. In other words, when the shift lever 60 is in the first position of
In
The electric actuator 85 is attached to a left side surface of the reduction gear case 33, and is provided therein with an electric motor 85a, a reduction gear mechanism 85b having a plurality of reduction gears, and a potentiometer 85c attached to an end of any rotational shaft of the reduction gear mechanism 85b (e.g., the output shaft 85d on the most downstream side of driving force).
[The Configuration of the Waiting Mechanism 83]In
The drive cylindrical shaft 91 is integrally formed with a left end wall 91a, and the driven cylindrical shaft 92 is integrally formed with a right end wall 92a. An inside diameter of the drive cylindrical shaft 91 and an inside diameter of the driven cylindrical shaft 92 are substantially same. The left end wall 91a of the drive cylindrical shaft 91 has a pin engaged hall 91c at an eccentric position distant from the cylindrical shaft axis O2. The aforementioned eccentric drive pin 85e, formed on the output shaft 85d of the electric actuator 95, is engaged with the pin engaged hall 91c.
The coil spring 93 is arranged between the left end wall 91a and right end wall 92a. One end (right end) 93a of the coil spring 93 is engaged with an engaging hall 92b formed the right end wall 92a of the driven cylindrical shaft 92, and the other end (left end) 93b of the coil spring 93 is engaged with an engaging hall 91b formed the left end wall 91a of the drive cylindrical shaft 91.
A center line of the coil spring 93 is coincided with the cylindrical shaft axis O2, and the coil spring 93 has a waiting function. Namely, the operating power from the electric actuator 85 can be temporarily accumulated by twisting the coil spring 93 around the cylindrical shaft axis O2.
However, the waiting function of the waiting mechanism 83 is restricted by a waiting action restricting mechanism. The waiting action restricting mechanism is constituted by a restricting projection 96 and a restricting notch 97 so that the waiting function is effectively produced only when the drive cylindrical shaft 91 rotates in one rotating direction, and is not produced when the drive cylindrical shaft 91 rotates in another rotating direction. In the embodiments, the operating power can be temporarily accumulated only when the shift lever 60 is moved from the first position of
The waiting action restricting mechanism will be specifically described. In
In the case that the shift lever 60 in the condition of
When the two-wheel-drive/four-wheel-drive switching mechanism 31 of
In addition, in
[A Switching Operation from the Two-Wheel-Drive Condition to the Four-Wheel-Drive Condition]
As shown in
At the time of this operation, when the end faces of the dog teeth 70 and 71 of the two-wheel-drive/four-wheel-drive switching mechanism 31 are abutted to each other, a waiting action of the waiting mechanism 83 is exerted. In other words, only the drive cylindrical shaft 91 is rotated from the condition shown in
At the time of the waiting action of
When the shift lever 60 reaches the second position of
[A Switching Operation from the Unlocked Condition to the Locked Condition in the Four-Wheel-Drive Condition]
When the four-wheel-drive condition is maintained and the differential lock mechanism 39 is switched from the unlocked condition to the locked condition, the electric actuator 85 is driven to further rotate the waiting mechanism 83 in the direction indicated by the arrow Q1 of
At the time of this operation, when the end faces in an axial direction of the inner spline teeth 54 and the outer spline teeth 53 are abutted onto each other, the waiting action of the waiting mechanism 83 is exerted. In other words, only the drive cylindrical shaft 91 is rotated from the condition shown in
At the time of the waiting action of
As shown in
[Switching from the Locked Condition to the Unlocked Condition]
When the shift lever 60 is returned from the third position of
At the time of this operation, the restricting projection 96 and the end face 97b in the direction indicated by the arrow Q2 of the restricting notch 97 are abutted onto each other all the time, so that the waiting action of the waiting mechanism 83 is not produced. In other words, the first drive pin 56a is moved in the direction indicated by the arrow D2 so as to release the engagement of the inner spline teeth 54 and the outer spline teeth 53 of the differential lock mechanism 39 of
[Switching from the Four-Wheel-Drive Condition to the Two-Wheel-Drive Condition]
When the shift lever 60 is returned from the second position of
(a) In
(b) In
(c) In
(d) In
(e) On the other hand, the differential lock mechanism 39 is switched from the locked condition to the unlocked condition and when the two-wheel-drive/four-wheel-drive switching mechanism 31 is switched from the four-wheel-drive condition to the two-wheel-drive condition, the operating power of the coil spring 93 is not accumulated, so that a quick-response and immediate operation can be performed.
(f) In
(g) In
(h) In
(i) In
(j) In
(k) The potentiometer for detecting the amount of rotation is provided on the rotating member arranged in the electric actuator 85, so that the amount of operating power from the electric actuator to the waiting mechanism 83 can be easily detected.
(l) In
(1) In the structure shown in
(2) In the present invention, the outside diameter of the drive cylindrical shaft 91 and the outside diameter of the driven cylindrical shaft 92 may be different from each other.
(3) In the above embodiment, the engine (internal-combustion engine) is provided as the driving source for generating driving force for driving the vehicle, but the present invention is also applicable to a vehicle equipped with an electric motor, a hydraulic motor, or a diesel engine, as the driving source.
(4) In the above embodiment, the two-wheel-drive/four-wheel-drive switching mechanism is provided as a first power switching mechanism, and the differential lock mechanism for front wheels is provided as a second power switching mechanism. However, the present invention is applied to a differential lock mechanism for rear wheels and a two-wheel-drive/four-wheel-drive switching mechanism. In addition, other power switching mechanisms for vehicle, for example various clutch mechanisms, a High-Low speed switching mechanism and so on, may be utilized.
(5) In the above embodiment, the waiting mechanism is constituted so that the waiting action of the waiting mechanism is produced in only one rotating direction. However, in the present invention, the waiting mechanism may be constituted so that the waiting action is produced in any rotating direction.
(6) An electric actuator into which the potentiometer is not incorporated can also be provided.
(7) The present invention is not limited to the configuration of the above embodiment and includes various modification examples contemplated in the scope without departing from the contents described in the claims.
Claims
1. A power switching device for vehicle, the switching device comprising:
- at least first and second power switching mechanisms arranged on the way of a driving force transmission passage from a driving source to wheels;
- a shared operating mechanism to switch both of the first and second power switching mechanisms on and off; the shared operating mechanism having a waiting mechanism; and
- a housing accommodating the first and second power switching mechanisms and the shard operating mechanism, the housing being integrally formed with a boss portion having the waiting mechanism built-in, wherein:
- the waiting mechanism includes a drive cylindrical shaft located in an operation side, a driven cylindrical shaft located in an actuation side, and a coil spring connecting the driven cylindrical shaft with the drive cylindrical shaft so as to transmit an operating power,
- both of the drive and driven cylindrical shafts and the coil spring are arranged in a same cylindrical shaft axis,
- the drive cylindrical shaft is supported on an inner peripheral surface of the boss portion through a drive side needle roller bearing, and the driven cylindrical shaft is supported on the inner peripheral surface of the boss portion through a driven side needle roller bearing, and
- the coil spring is arranged inside the drive cylindrical shaft and the driven cylindrical shaft.
2. The power switching device for vehicle as claimed in claim 1, wherein
- the drive cylindrical shaft and the driven cylindrical shaft have substantially a same outside diameter,
- an inner peripheral surface of the boss portion has an uniform inside diameter, and
- the drive side needle roller bearing and the driven side needle roller bearing are arranged next to each other on the cylindrical shaft axis direction, and are retained by a shared retainer.
3. The power switching device for vehicle as claimed in claim 2, wherein
- one of the drive cylindrical shaft and the driven cylindrical shaft is formed with an arcuate notch about the cylindrical shaft axis and the other is formed with a projection for engaging with the notch so as to be movable in a circumferential direction, and
- only when at least one of the first and second switching mechanisms is operated from a disengaged condition of the power to an engaged condition, the projection and the notch are relatively moved in the circumferential direction to compress the coil spring.
4. The power switching device for vehicle as claimed in claim 3, wherein
- the notch and the projection are located in a position corresponding to a boundary between the drive side needle roller bearing and the driven side needle roller bearing in the cylindrical shaft axis direction, and opposite to the above boundary from inside in a radial direction of the cylindrical shafts.
5. The power switching device for vehicle as claimed in claim 1, wherein
- the first switching mechanism is a two-wheel-drive/four-wheel-drive switching mechanism, and
- the second switching mechanism is a differential lock mechanism which can lock a differential device.
6. The power switching device for vehicle as claimed in claim 5, wherein
- the shared shift lever of the shared operating mechanism can be switched among a first position, a second position, and a third position,
- when the shared shift lever is located in the first position, the two-wheel-drive/four-wheel-drive switching mechanism is in a two-wheel-drive condition, and the differential lock mechanism is in an unlocked condition,
- when the shared shift lever is located in the second position, the two-wheel-drive/four-wheel-drive switching mechanism is in a four-wheel-drive condition, and the differential lock mechanism is in the unlocked condition, and
- when the shared shift lever is located in the third position, the two-wheel-drive/four-wheel-drive switching mechanism is in the four-wheel-drive condition, and the differential lock mechanism is in a locked condition,
Type: Application
Filed: Feb 27, 2013
Publication Date: Aug 28, 2014
Applicant: KAWASAKI JUKOGYO KABUSHIKI KAISHA (Hyogo)
Inventor: Hideaki KII (Kakogawa-shi)
Application Number: 13/778,657
International Classification: F16H 61/68 (20060101);