This application is based on and claims priority from Japanese Patent Application No. 2017-139726, filed on Jul. 19, 2017; the disclosure of which is hereby incorporated by reference herein in its entirety.
The present invention relates to a vehicle door latch apparatus, particularly to a vehicle door latch apparatus that includes a powered cinching mechanism that displaces a latch from a half-latched position to a full-latched position.
Conventionally, there is known a vehicle door latch apparatus that includes a power release mechanism that releases the restraint of a latch by means of motor power in order to make a door openable (Patent Literature 1). There is also known a vehicle door latch apparatus that includes a powered cinching mechanism (also referred to as a powered closing mechanism) that shifts a latch from a half-latched position to a full-latched position (Patent Literature 2).
Patent Literature 1: JP2002-295095A
Patent Literature 2: JP2016-98628A
Conventionally, the power source of a power release mechanism, which does not need high output power, is often provided integral with a latch unit having a latch and a ratchet. On the contrary, the power source of a powered cinching mechanism, which needs high output power, is often arranged near the center of a vehicle door, separate from the latch unit.
The latch unit is subject to many restrictions in design because it is fixed in a narrow and limited space of the rear end portion of a vehicle door that is furthest away from the rotation axis thereof. On the contrary, the power source of a powered cinching mechanism that is separately provided has much higher design flexibility. However, even a powered cinching mechanism of a luxury car generates a loud operation noise. The noise is reduced by a large amount of sound-proofing and sound-absorbing material that is used in the vehicle door.
A vehicle door latch apparatus of the present invention comprises:
a latch unit that is attached to an end portion of a vehicle door, the latch unit including:
a cable that rotates the first cinching lever; and
a power unit that is attached to the vehicle door and that is separated from the latch unit, the power unit including a motor, a cable drum onto which one end of the cable is wound and that takes up and feeds the cable, a deceleration mechanism that transfers power of the motor to the cable drum, and a closed-type housing that houses the motor, the cable drum and the deceleration mechanism.
Operation noise at 300 mm right above the housing of the power unit is 42.2 to 40.9 dB at a supply voltage to the motor of 9V, 47.5 to 43.9 dB at a supply voltage of 12V, and 49.7 to 46.5 dB at a supply voltage of16 V.
The deceleration mechanism includes a worm gear and a helical gear.
According to the present invention, the operation noise of a power unit can be reduced to a satisfactory level, and cost also can be saved.
The above and other objects, features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings which illustrate examples of the present invention.
An embodiment of the present invention will be described with reference to the drawings. The present invention can be applied to a normal swing-type vehicle door, but the present invention can also be applied to a sliding-type vehicle door.
Vehicle door latch apparatus 10 has latch unit 12, operation unit 13 and power unit 14. Latch unit 12 is fixed to the rear end of the vehicle door (inside door panel 11). Operation unit 13 is arranged on the back side of and adjacent to latch unit 12. Power unit 14 supplies door cinching power to operation unit 13. The door cinching power is used to fully latch the vehicle door. It should be noted that latch unit 12 and operation unit 13 are not strictly differentiated or separated and that these can also be grasped as latch assembly 12, as a whole.
Latch unit 12 is arranged at the rear end of a vehicle door, which is the farthest part from the rotational shaft of the vehicle door, such that the front side illustrated in
When the vehicle door is moved in the door closing direction with a sufficiently large manual door closing force, striker 15 relatively goes into striker passage 18a that is formed in latch body 18 and then abuts against striker engaging groove 16a of latch 16 that is in the unlatched position, as depicted by the imaginary line in
As shown in
As shown in
First cinching lever 25 (
As shown in
Clutch lever 30 is provided with substantially horizontal bearing surface 30a, which supports movable shaft 29 of first cinching lever 25 from below. Movable shaft 29 is only placed on bearing surface 30a without being rotatably supported by any immobile element, such as latch body 18 or bracket 23. First cinching lever 25 functions based on the principle of leverage, in which follower pin 28 is the point of effort, connecting pin 26 is the point of load and movable shaft 29 (bearing surface 30a) is the fulcrum. When the driving force of power unit 14 pushes down follower pin 28, which is the point of effort, first cinching lever 25 is rotated about the “fulcrum” in the anticlockwise direction and raises second cinching lever 27.
Guide pin 33 is provided in the upper part of second cinching lever 27. Guide pin 33 slidably engages vertical guide groove 18b that is formed on the front surface of latch body 18. Latch pushing end 27a is provided at the top end of second cinching lever 27. Latch pushing end 27a can abut against latch arm 16d of latch 16 in the half-latched position by being raised, and thus can rotate latch 16 to the fully-latched position.
When the door is open, first cinching lever 25 is biased in the clockwise direction in
As descried above, movable shaft 29 of first cinching lever 25 is only supported by bearing surface 30a of clutch lever 30 from below. This feature largely contributes to the disconnection of the power transmission path between power unit 14 and second cinching lever 27. Specifically, the power transmission path can be disconnected by depriving movable shaft 29 (bearing surface 30a), which is the fulcrum of lever, of the function of a “fulcrum”. The power transmission path can be quite easily disconnected by rotating clutch lever 30 in the anticlockwise direction in
Emergency lever 35 is rotatably supported by shaft 36 above another end 25b of first cinching lever 25 and on the back side of latch body 18. Bent portion 35a of emergency lever 35 is opposite to abutting part 30b of clutch lever 30. Emergency lever 35 is biased in the anticlockwise direction in
As shown in
Clutch lever 30 is rotated in the clockwise direction by the elastic force of clutch spring 32 when clutch lever 3 is disconnected from emergency lever 35. Bearing surface 30a moves beneath movable shaft 29 of first cinching lever 25 that has lost the function of a “fulcrum”, and returns to the waiting position shown in
As shown in
Side housing portion 24b houses door-opening motor 40 that is much smaller than power unit 14. Cylindrical worm gear 41 of motor 40 engages worm wheel gear 42. Worm wheel gear 42 is rotatably supported by main casing 24a via wheel shaft 42b that extends in the door width direction, and cam groove 42a is formed on the wheel surface thereof.
In the vicinity of worm wheel gear 42, door opening lever 43 is rotatably supported by main casing 24a via opening shaft 44. Follower pin 45 is formed on cam arm 43a of opening lever 43 that extends leftward in
Worm wheel gear 42 is usually kept at the position illustrated in
Vertical opening link 47 (
Bent abutting part 47b is provided at or near the center of opening link 47 in the vertical direction. The lower surface of bent abutting part 47b is opposite to the end of abutting arm 43b of opening lever 43 that extends rightward in
The upper surface of bent abutting part 47b of opening link 47 is opposite to ratchet pin 17b that is positioned at the end of ratchet 17. When opening link 47 is raised, ratchet 17 is rotated in the clockwise direction in
Since motor 40 that disengages ratchet 17 from latch 16 by motor power is housed in side housing portion 24b of housing 24 that is covered with casing cover 24c, the operation noise is shielded and sound pressure is limited within an appropriate range. Furthermore, the driving force of motor 40 is transmitted through both cam groove 42a that is formed on wheel gear 42 and follower pin 45 that is formed on opening lever 43. This achieves proper sound pressure and sound quality.
In principal, opening lever 43 (opening link 47) of the present invention is rotated in the opening direction (moved in the opening direction) by the driving force of motor 40. Motor 40 is activated by a detection signal from detection sensor 48 that is provided on a door grip of a vehicle door or the like or by an opening signal from remote transmitter 49 that is held by a driver. Accordingly, in vehicle door latch apparatus 10 of the present invention, a so-called “locking mechanism” that shifts between the locked state and the unlocked state and that is essential in the conventional vehicle door latch apparatus is omitted, and the structure is significantly simplified. In other words, disconnecting means to disconnect the power transmission path, such as “locking mechanism”, can be omitted because motor 40 can only be activated by a specific person.
In order to cope with malfunction of motor 40 or of the power transmission path, two safety measures are adopted. The first measure is achieved by door key cylinder 50. Door key cylinder 50 is provided on the outside metal door panel (not illustrated) of the vehicle door. A conventional door key cylinder is connected to a “locking mechanism”, which is not provided in the present invention, and the locking mechanism is used for shift between the locked state and the unlocked state. On the other hand, in the present invention, door key cylinder 50 is connected to auxiliary opening lever 51 that is provided in side housing portion 24b of housing 24. Auxiliary opening lever 51 is connected to the upper end of connecting rod 52, and bottom end 52e of connecting rod 52 is connected to vertical slot 47c of opening link 47 with play in the vertical direction.
Due to this arrangement, it is possible to raise opening link 47 via connecting rod 52, to disengage ratchet 17 from latch 16 and thereby to place the door in the openable state even under an unexpected circumstance by rotating door key cylinder 50 by means of a proper key plate.
The second measure is achieved by providing inside door opening handle 53 on the inner side of a vehicle door and by connecting inner lever 54 that is provided in side housing portion 24b of housing 24 to inside opening handle 53. Inner lever 54 is rotated in the clockwise direction about inner shaft 55 in
In the arrangement described above, there is also an advantageous feature in the structure in which the bottom part of opening link 47 is supported by connecting arm 35b of emergency lever 35. In daily operation, opening link 47 that is raised only by the power of motor 40 activates clutch lever 30 via emergency lever 35 and inactivates the “fulcrum” of first cinching lever 25 each time opening link 47 is raised. Accordingly, even when second cinching lever 27 is raised to and stopped at the fully-latched position due to a malfunction of power unit 14, second cinching lever 27 quickly returns to the lower waiting position by the elastic force of return spring 39 and allows latch 16 to rotate in the releasing direction without any interference from second cinching lever 27 because when motor 40 is activated by an operation signal, the “fulcrum” of first cinching lever 25 is simultaneously inactivated.
In addition, the arrangement in which opening link 47 is supported by emergency lever 35 simplifies the structure and enables rational design.
As shown in
As shown in
Power unit 14 is a sound-proofing and vibration-proofing power unit. Due to the synergy with sound-proofing and sound-absorbing cover 62, excellent sound pressure and sound quality can be obtained, as compared to an arrangement in which power unit 14 is arranged on the back side of a metal surface of inside door panel 11 such that it overlaps the metal surface of inside door panel 11, as seen in the door width direction.
As is well illustrated in
Drive system housing chamber 64a of main body 64 houses motor 67 that serves as a power source, cable drum 68 that takes up and feeds cable 58 and deceleration mechanism 69 that transfers the power of motor 67 to cable drum 68. By taking up cable 58 onto cable drum 68, power lever 57 of operation unit 13 is rotated and first cinching lever 25 is activated.
As shown in
Two-stage gear 70, which is a main element of deceleration mechanism 69, is integrally molded from a resin. Support shaft 71 that is formed in main body 64 is inserted through hollow center shaft 70a so that center shaft 70a is rotatably supported by main body 64. Large-diameter gear 70b of two-stage gear 70 is a worm wheel gear that engages cylindrical worm 72 that is attached to the output shaft of motor 67. Small-diameter gear 70c that is coaxial with large-diameter gear 70b is a helical gear (a cylindrical gear having helix-shaped teeth). Drum gear 68a in the shape of a helical gear that engages small-diameter gear 70c is formed on the outer peripheral surface of cable drum 68.
In power unit 14 of vehicle door latch apparatus 10 that is used for a normal hinge-type vehicle door, an output of about 615 N (newton) is required as a force to pull cable 58 at the outer end thereof (at the end portion on the side of latch unit 12, or at the end that is coupled to operation unit 13) at an ambient temperature of 23° C. and a at a supply voltage of 12V. The corresponding output of power unit 14 is about 315.5 to 1144 N at an ambient temperature of −40 to 80° C. and at a supply voltage of 9 to 16V. The output of motor 67 of power unit 1 can be about 210 N under the same conditions when using deceleration mechanism 69 having the worm gear and the helical gear.
There is no movable member arranged in rear space 64b of main body 64. In the embodiment, a circuit board (not illustrated) that is connected to electric cables 73 is arranged in rear space 64b. Electric cables 73 include a power line to motor 67 and a signal line of drum sensor 74 that detects the rotational position of cable drum 68. Drum sensor 74 functions by coming into contact with cam protrusion 68b of cable drum 68 and detects the initial position of cable drum 68 (the position at which the cable is fed).
When latch 16 is in the half-latched position, motor 67 rotates cable drum 68 in order to pull and take up cable 58. When latch 16 comes to the full-latched position, motor 67 is reversed and rotates cable drum 68 in the reverse direction in order to feed cable 58. When cable drum 68 returns to the initial position, cam protrusion 68b comes into contact with drum sensor 74. Motor 67 stops and power unit 14 returns to the initial state.
Since rear space 64b where no movable member is provided is covered with back cover 66, the operational performance that reduces and insulates the operational noise of the movable members, which are provided in drive system housing chamber 64a on the back side of rear space 64b, is improved.
A plurality of connecting elements 75 is provided on the outer periphery of main body 64 of power unit 14, and each connecting element 75 is fixed to the end portion of each attachment plate 61 via vibration damping rubber 76 (
Motor 67 of power unit 14 is a DC brush motor. As shown in the schematic diagram of
As described above, power unit 14 according to the present invention is provided with a large number of sound-proofing, vibration-proofing and vibration-damping measures, thereby achieving satisfactory reduction of operational noise, as compared to a conventional product with the same level output. As an example, power unit 14 was attached to an immobile member (equivalent to inside door panel 11), in which no element corresponding to sound-proofing and sound-absorbing cover 62 was provided, and the operational noise of power unit 14 was measured independently. A microphone for measurement (LA-5111 produced by Ono Sokki Co., Ltd.) was installed 300 mm right above power unit 14.
The operational noise of power unit 14 according to the example at an ambient temperature of 23° C. ranged between 42.2 to 40.9 dB at a voltage of 9V, 47.5 to 43.9 dB at a voltage of 12V, and 49.7 to 46.5 dB at a voltage of 16V.
Although several preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications can be made without departing from the spirit or scope of the appended claims.
Number | Date | Country | Kind |
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2017-139726 | Jul 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/038061 | 10/20/2017 | WO | 00 |