Applicants hereby claim foreign priority benefits under U.S.C. § 119 from Japanese Patent Application No. 2003-350566, filed on Oct. 9, 2003, the content of which is incorporated by reference herein.
The present invention relates to an automatically opening/closing apparatus for vehicle, which automatically opens and closes an opening/closing member mounted on a vehicle body and more particularly to a rack-and-pinion type one that has a pinion rotate-driven by a drive source and a rack engaged with the pinion.
Conventionally, throughout a vehicle such as an automobile, an opening/closing member openably and closably mounted on the vehicle, such as a door, a trunk lid, and a back door, has been provided. Particularly, a station wagon, a one-box car, or the like is provided in many cases with a back door at a rear end of the vehicle so as to facilitate loading and unloading of baggage from a rear side of the vehicle. Usually, this kind of back door is mounted on the vehicle body through a hinge fixed to a rear end of a vehicle roof with a supporting point for rotation being substantially horizontal, thereby being opened and closed vertically around the supporting point for rotation of the hinge, which serves as its center. In this case, the back door is also called a lift gate or rear hatch or the like since it is largely swung in an upper direction of the vehicle.
However, since such a back door is large and heavy in most cases, there is the problem that women or children cannot particularly open or close the back door easily. Specifically, when it is opened fully, the back door is largely swung upward and therefore it is more difficult to close the door.
For this reason, under the condition of increase in family use of a one-box car or the like, a vehicle equipped with an automatically opening/closing apparatus that automatically opens/closes the back door has been developed so that even women and children can easily open and close. Because such an automatically opening/closing apparatus allows the back door to be controlled remotely from a driver's seat, demands for installation of the automatically opening/closing apparatus are frequently made due to such convenience.
As such an automatically opening/closing apparatus, a so-called rack-and-pinion type one, which comprises a pinion driven by a driving unit serving as an electric motor and a rack having rack teeth each engaged with this pinion, has been well known in, for example, Japanese Patent Laid-open No. 2001-253241. In this case, the rack is formed into a stick shape, and is connected to the back door through a connecting rod and concurrently accommodated in a channel to be supported in a linearly reciprocable manner by the channel. Then, if the pinion is rotate-driven by the electric motor, a linear reciprocation of the rack is transmitted to the back door through the connecting rod, whereby the opening/closing operation of the back door is performed.
Further, as such a rack-and-pinion type of automatically opening/closing apparatus, there has been well known a so-called outer rack type one in which an outer rack formed substantially into a “C” shape in sectional view is mounted outside a guide rail in a linearly reciprocable manner.
However, in such a rack-and-pinion type of automatically opening/closing apparatus, the channel and the guide rail need to be supported throughout the entire operating range of the rack. Thus, the guide rail is formed to become substantially twice as long as the entire length of the rack in dimension, whereby the automatically opening/closing apparatus for vehicle grows in size and gets heavy.
Further, in the outer rack type of automatically opening/closing apparatus, the rack is formed so as to have a C-shaped section throughout the entire length by an undercut processing etc. However, such a processing is very difficult to perform.
An object of the present invention is to reduce in size and weight an automatically opening/closing apparatus for rack-and-pinion type vehicle.
A automatically opening/closing apparatus for vehicle according to the present invention, which has a rack connected to an opening/closing member mounted on a vehicle and a drive source for rotate-driving a pinion engaged with rack teeth of said rack so as to automatically open/close said opening/closing member, comprises: a slide mechanism including a slide portion provided on a side of an axial-direction end of said rack and a guide member engaged with said slide portion and thereby supporting linearly reciprocably said rack; and a holding member contacting with a holding face of said rack, which is formed on a rear side with respect to said rack teeth, and thereby maintaining an interval between said rack and said pinion.
In the automatically opening/closing apparatus for vehicle according to the present invention, a plurality of said holding members are each arranged along said holding face with a predetermined space.
The automatically opening/closing apparatus for vehicle according to the present invention further comprises an elastic member mounted on said the holding member and biasing said rack in a direction away from said pinion.
According to the present invention, since the length dimension of the slide member guided by the guide member can be reduced, the automatically opening/closing apparatus for vehicle can be reduced in size and weight.
Also, according to the present invention, since the length dimension of the guide member, which constitutes the slide mechanism for supporting linearly reciprocably the rack, can be reduced to a degree of the length dimension of the rack, the automatically opening/closing apparatus for vehicle can be reduced in size and weight.
Further, according to the present invention, since the interval between the rack and the pinion is held at an interval suitable for the engagement thereof by the holding member, the engagement of the rack and the pinion can be stabilized. Therefore, noise, and vibration, etc. generated during the actuation of the automatically opening/closing apparatus for vehicle can be reduced.
Further, according to the present invention, since the slide member, the rack, and the guide member, etc. can be modified easily depending on each specification, the general-purpose characteristics of the automatically opening/closing apparatus for vehicle can be improved.
Additionally, according to the present invention, by providing a plurality of holding members, torsion etc. of the rack can be suppressed even if a large load is applied from the opening/closing member. Therefore, noise, and vibration, etc. generated during the actuation of the automatically opening/closing apparatus for vehicle can be further reduced.
Hereinafter, an embodiment of the present invention will be detailed based on the drawings.
As shown in
Note that a gas stay, which assists the opening/closing operation of the back door 12, may be provided between the vehicle 11 and the back door 12.
Since this vehicle 11 is provided with an automatically opening/closing apparatus for vehicle 15 (hereinafter abbreviated as “opening/closing apparatus 15”), the back door 12 is automatically opened and closed by this opening/closing apparatus 15. The opening/closing apparatus 15 comprises an actuator unit 16 disposed inside a rear pillar of the vehicle 11 and a connecting rod 17 for transmitting output of the actuator unit 16 to the back door 12.
As shown in
Meanwhile, the actuator unit 16 has a base 21 and is fixed to the vehicle 11 through the base 21. A drive unit 24, comprising an electric motor 22 as a drive source and a reduction gear 23, is installed on the base 21, and the electric motor 22 is connected to a control unit (not shown), thereby being controlled by the control unit. As such a control unit, a microcomputer including CPU, and memory, etc. is employed and outputs a control current to the electric motor 22 according to an instruction signal sent from a back-door opening/closing switch (not shown) provided to a vehicle compartment etc. Then, the electric motor 22 is operated in a normal/inverse direction depending on a control current supplied from the control unit.
As shown in
Also, a friction type electromagnetic clutch 33 is provided inside the gear case 25, so that drive power between the reduction gear mechanism 26 and the output shaft 31 can be intermittently transmitted by the electromagnetic clutch 33. Therefore, when the back door 12 is opened and closed manually, the electromagnetic clutch 33 is shifted to a power-cutoff condition, so that an operating force at the time of operating manually the back door 12 can be reduced.
As shown in
A gear transmission mechanism 44 is provided in the actuator unit 16, and the rotary motion of the pinion shaft 41 rotate-driven by the electric motor 22 is converted to the reciprocation of the connecting rod 17 by the gear transmission mechanism 44.
As shown in
The pinion 46 is fixed on the pinion shaft 41 and rotate-driven by the electric motor 22 together with the pinion shaft 41. Meanwhile, the rack 45 made from steel plate is formed into a substantially rectangular shape, and one side of the rack is provided with rack teeth 45a arranged axially. Also, the rack teeth 45a of the rack 45 are mutually engaged with teeth of the pinion 46, and if the pinion 46 is rotated in a normal/inverse direction by the electric motor 22, the rotation thereof is transmitted to the rack 45 and thereby the rack 45 reciprocates.
Also, a slide block 47 as a slide portion is provided at one end of the rack 45 on a vehicle-upper side while a guide rail 48 as a guide member is fixed to the base 21. The rack 45 is engaged with the guide rail 48 serving as the guide member in the slide block 47 and is supported linearly reicprocably by the guide rail 48 in the slide block 47, and thereby its moving direction is restricted. That is, the slide block 47 and the guide rail 48 constitute a slide mechanism 49, so that the rack 45 is supported linearly reicprocably by this slide mechanism 49 with respect to the base 21.
As shown in
Meanwhile, the guide rail 48 is fixed to the base with bolts (not shown) so that its axial direction is directed to a substantially vertical direction of the vehicle 11. The slide block 47 is mounted at the outside of the guide rail 48 within the sliding groove 47a to be guided movably along the guide rail 48. That is, this slide mechanism 49 is of a so-called outer rack type one in which the slide block 47 of the rack 45 is installed outside the guide rail 48.
With this structure, the rotation of the pinion 46 rotate-driven by the electric motor 22 is converted to the linear reciprocation of the rack 45, and the linear reciprocation is transmitted to the back door 12 through the connecting rod 17 so as to achieve the automatically opening/closing operation of the back door 12. In this case, the rack 45 becomes linearly reciprocable substantially in the vertical direction with respect to the vehicle 11 between a close-side stroke end indicated by the solid line in
A pair of sliding members 53a and 53b are mounted in the sliding groove 47a of the slide block 47, and so sliding friction between the slide block 47 and the guide rail 48 is reduced by these sliding members 53a an 53b. Note that since the sliding members 53a and 53b have the same structure and function except that their shapes are symmetrical, only the sliding member 53a will be described below.
The sliding member 53a is formed by: pressing a sheet material in which a thin resin plate is attached to a surface of a copper plate; and punching out and shaping it to have a predetermined shape. The sliding member 53a comprises: a base portion 54 formed into a semi-circle shape to be disposed in the sliding groove 47a; and a substantially rectangular engaging portion 55 provided integrally to the base portion 54. A surface inside the base portion 54, that is, on a side that comes in contact with the guide rail 48 is a low friction surface to which a resin sheet is attached, and the base portion 54 makes a slidable contact with the guide rail 48 through the low friction face. Meanwhile, a rectangular engaging hole 56 that opens substantially at the center of the sliding groove 47a is formed in the slide block 47. The interval between both side faces 56a perpendicular to the axial direction of this engaging hole 56 is substantially the same as the axial-direction width dimension of the engaging portion 55 provided to the sliding member 53a.
This sliding member 53a is mounted on the slide block 47 by: disposing the base portion 54 in the sliding groove 47a of the slide block 47; and bending the engaging portion 55 with respect to the base portion 54 to be engaged with the engaging hole 56. That is, when the sliding member 53a is mounted in the slide block 47, as shown in
In a state of holding temporarily the base portion 54 in the sliding groove 47a, the engaging portion 55 is disposed so as to close the engaging hole 56 formed in the slide block 47. By bending the engaging portion 55 into the engaging hole 56 from the above-mentioned state along the axial direction of the guide rail 48 using a press machine etc., as shown in
In this case, an axial-direction load applied to the base portion 54 due to the friction with the guide rail 48 is supported by the slide block 47 in the engaging portion 55. However, both of the end faces 55a of the engaging portion 55 are engaged with the side faces 56a of the engaging hole 56. Therefore, even if the large axial-direction load is applied to the base portion 54, the load can be supported easily. That is, the load applied to the base portion 54 acts as not a bending force but a shearing force to the engaging portion 55 and further the shearing force is applied in a direction extending along a boundary between the base portion 54 and the engaging portion 55. Thus, even if the engaging portion 55 is formed of the sheet material, it is never sheared easily, so that high resistance to the axial-direction load occurs. Accordingly, even if the sliding member 53a generates high resistance against the guide rail 48 and thereby an escaping-direction load acts on the base portion 54, the base portion 54 can be prevented from deviating from or being disconnected from the slide block 47.
Thus, in this opening/closing apparatus 15, since the sliding members 53a and 53b to be mounted on the slide block 47 is provided with the engaging portion 55 to be engaged with the slide block 47, it is possible to prevent the axial-direction deviation or disconnection of the sliding members 53a and 53b with respect to the slide block 47.
Further, in this opening/closing apparatus 15, since the engaging portions 55 provided on the sliding members 53a and 53b are bent along the axial direction of the guide rail 48 and is engaged with the engaging hole 56 provided in the slide block 47, the durability and strength of the engaging portion 55 with respect to the axial-direction load can be enhanced.
Also, since the sliding members 53a and 53b are each formed by pressing the sheet material and punching out it into the predetermined shape, dimensional accuracy of the axial-direction width of the engaging portion 55 is enhanced, so that both end faces 55a of the engaging portion 55 can be engaged with both side faces 56a of the engaging hole 56 without any gap. Consequently, axial-direction play of the base portion 54 with respect to the slide block 47 can be eliminated, whereby it is possible to reduce abnormal noise due to the play of the base portion 54, and abnormal wearing of the base portion 54, and the like.
As shown in
The holding member 61 comprises: a holding shaft 62 inserted into a through hole 48a formed on one end side of the guide rail 48 so as to oppose the pinion shaft 41; and a roller 63 mounted outside the holding shaft 62. The roller 63 is rotatable to the holding shaft 62. Meanwhile, a groove portion 64 axially extending is formed in the rack 45, and the above-mentioned roller 63 is disposed in this groove portion 64. Also, a surface, which is on a rear side opposite to the rack teeth 45a of the groove portion 64, acts as a holding face 65, and the above roller 63 can contact with the holding face 65. Therefore, even if a load in a direction away from the pinion shaft 41 is applied to the rack 45 due to the engaging resistance between the rack teeth 45a and the pinion 46, and vibration from the outside, etc., the load is supported by the roller 63, that is, the holding shaft 62, so that the movement of the rack 45 in the direction away from the pinion shaft 41 is restricted. Namely, the interval between the rack 45 and the pinion 46 is maintained due to the holding member 61 comprising the roller 63 contacting with the holding face 65 and the holding shaft 62, whereby the engagement between the rack teeth 45a of the rack 45 and the pinion 46 is kept under an appropriate condition.
As described above, the slide block 47 supported linearly reciprocably by the guide rail 48 is formed at the sufficient short length dimension with respect to the entire length of the rack 45, so that when the load in the direction away from the pinion shaft 41 is applied to an opposite end at which the slide block 47 of the rack 45 is provided, it is difficult to support the load by the slide block 47. However, in this opening/closing apparatus 15, the movement in the direction away from the pinion 46, that is, the interval between the rack 45 and the pinion 46 is maintained by the holding member 61, so that even if the axial-direction dimension of the slide block 47 is formed to be sufficiently short with respect to the entire length of the rack 45, the engagement between the rack 45 and the pinion 46 can be ensured. Therefore, in the opening/closing apparatus 15, by making the axial-direction length dimension of the slide block 47 short, it is possible to reduce the opening/closing apparatus 15 in size and weight.
Also, by shortening the axial-direction length of the slide block 47, the axial-direction length of the guide rail 48 can be shortened accordingly. That is, since the operating range of the slide block 47 is reduced depending on the reduction in the axial-direction length thereof, the axial-direction length of the guide rail supporting the slide block 47 can be shortened. Consequently, the opening/closing apparatus 15 can be further reduced in size and weight.
Thus, in the opening/closing apparatus 15, since the rack 45 is supported linearly reciprocably by the guide rail 48 through the slide block 47 and the interval between the rack 45 and the pinion 46 is held by the holding member 61, the opening/closing apparatus 15 can be reduced in size and weight by shortening the length dimension of the slide block 47 and the guide rail 48. Also, since the interval between the rack 45 and the pinion 46 is kept at an interval suitable for the engagement by the holding member 61, the operating noise and the vibration can be reduced by stabilizing the engagement of the rack teeth 45a of the rack 45 and the pinion 46.
Further, because the opening/closing apparatus 15 can be easily set by modifying slightly the slide block 47, the rack 45, the guide rail 48, the holding member 61, or the like so as to meet various specifications, the general-purpose characteristics of the opening/closing apparatus 15 can be improved.
As shown in
The supporting piece 72 comprises a fixing portion 72a to be fixed to the holding shaft 62, and a supporting column portion 72b projecting from the fixing portion 72a in an opposite direction to the pinion shaft 41, wherein the circular cushion rubber 74 is mounted in the supporting column portion 72b. The supporting piece 72 contacts with the guide rail 48, whereby the axial-direction movement with respect to the holding shaft 62 becomes restricted.
Meanwhile, the lower rack guide 73 is mounted on the holding shaft 62 so as to cover the supporting piece 72 and become movably in the direction of the engagement of the rack 45 and the pinion 46 and is concurrently supported slidably by the guide rail 48, whereby the axial-direction movement with respect to the holding shaft 62 is restricted. Also, the lower rack guide 73 is provided with a wall portion 73a contacting with the cushion rubber 74, and the cushion rubber 74 is disposed in an elastically deformed state in the supporting piece 72, namely, between the holding shaft 62 and the wall portion 73a. Consequently, the lower rack guide 73 is energized (biased) in a direction away from the pinion 46 due to the elastic force of the cushion rubber 74.
Also, as shown in
Thus, in the opening/closing apparatus 15, the rack 45 is always energized in such a direction that the holding face 65 contacts with the roller 63 due to the elastic force of the cushion rubber 74. Consequently, the noise generated by the vibration of the rack 45 between the pinion 46 and the roller 63 can be reduced.
Further, since the rack 45 is always energized in such a direction that the holding face 65 contacts with the roller 63 due to the elastic force of the cushion rubber 74, the interval between the rack 45 and the pinion 46 is always kept constant. Therefore, the engagement of the rack teeth 45a of the rack 45 and the pinion 46 is stabilized, whereby the operational noise and vibration generated from the engaging portion of the rack teeth 45a and the pinion 46 can be reduced.
Further, since the width dimension of the groove portion 64 provided to the rack 45 can be set to be sufficiently large with respect to the roller 63, there never arises the problem that the width of the groove portion 64 becomes too narrow due to processing errors etc. and thereby malfunctioning of the roller 63 occurs. Therefore, the processing of the groove portion 64 is facilitated and the quality of the opening/closing apparatus 15 can be improved.
Additionally, in the opening/closing apparatus 15, since the vibration damping mechanism 71 can be formed within the width dimension of the rack 45, the opening/closing apparatus 15 can be miniaturized. Particularly, when the opening/closing apparatus 15 is mounted inside the roof of the vehicle 11, the vertical dimension thereof is reduced and thereby the ceiling of the vehicle compartment can be made high.
As seen from
Further, between the rack 45 and the supporting cover 76, there are disposed an upper rack guide 81 as an axial-direction pressing member and a wave washer 82 as an axial-direction elastic member, which constitute the vibration damping mechanism 71. The upper rack guide 81 is movably mounted axially on the holding shaft 62, wherein one end thereof contacts with an axial-direction end face of the rack 45. Meanwhile, the wave washer 82 is elastically deformed and mounted between the upper rack guide 81 and the supporting cover 76. The upper rack guide 81 is always energized toward the rack 45 due to the elastic force of the wave washer 82. At this time, since a base-side end of the rack 45 contacts with the lower rack guide 73, the movement of the rack 45 becomes restricted on a side of the base 21. Therefore, the rack 45 is not needlessly moved toward the base 21 due to the elastic deformation of the wave washer 82. With this structure, the axial-direction vibration of the holding shaft 62 generated in the rack 45 is absorbed by the wave washer 82 and reduced.
Thus, in the opening/closing apparatus 15, since the rack is always energized axially due to the elastic force of the wave washer 82, the vibration of the rack 45 can be reduced even if vibration is applied to the rack 45 in stopping the operation.
In order to accommodate the reduction gear 43 therein, the base 21 for use in the actuator unit 16 is formed so as to be divided into two along the axial direction of the pinion shaft 41. That is, the base 21 comprises a first base body 83 and a second base body 84 which are assembled to each other, wherein the reduction gear 43 is accommodated in a gear accommodating portion 42 formed between the first and second base bodies 83 and 84 and the guide rail 48 is fixed to the first base body 83. Note that fastening members such as bolts and nuts (not shown), which are inserted into plural assembly holes provided in the respective base bodies 83 and 84, are used to assemble the base bodies 83 and 84.
The above-mentioned shaft supporting portion 35 is provided on the first base body 83. A pair of positioning bosses 85 and 86 are provided to the first base body 83 on a straight line passing the axis of the shaft supporting portion 35 and on both sides between which the shaft supporting portion 35, that is, the pinion shaft 41 is provided. Each of the positioning bosses 85 and 86 is formed into a cylinder shape projecting toward the second base body 84.
Meanwhile, the above-mentioned shaft supporting portions 34 and 36 are provided to the second base body 84. That is, the interval between the pinion shaft 41 and the output shaft 31 is set up depending on the shaft supporting portions 34 and 36 provided to the second base body 84. For this reason, since the first and second base bodies 83 and 84 are formed by pressing steel plates and, at this time, the respective shaft supporting portions 34 to 36 are formed, the interval between the pinion shaft 41 and the output shaft 31 can be set up with high accuracy by supporting the pinion shaft 41 and the output shaft 31 at the shaft supporting portions 34 and 36 provided to the second base body 84. Therefore, the accuracy of the engagement position between the reduction gear 43 fixed on the pinion shaft 41 and the output gear 32 fixed on the output shaft 31 can be improved and thereby the operating noise, vibration, and the like can be reduced.
Further, a pair of positioning holes 87 and 88 are provided to the second base body 84 on a straight line passing the axis of the shaft supporting portion 36 and on both sides between which the shaft supporting portion 36 is sandwiched. The positioning holes 87 and 88 are formed at such positions as to correspond to the positioning bosses 85 and 86 provided on the first base body 83, respectively. Also, the positioning hole 87 is formed into a circular shape having the same inside diameter as the outside diameter of the positioning boss 85 in dimension, and the positioning hole 88 is formed into an elongate hole whose the width dimension in a direction perpendicular to a straight line passing the shaft supporting portion 36 is equal to the outside diameter of the positioning boss 86 and whose the linear dimension is larger than the outside diameter of the positioning boss 86.
In assembling the first and second base bodies 83 and 84 to each other, the positioning of such assembly is achieved by engaging the positioning bosses 85 and 86 with the positioning holes 87 and 88, respectively. That is, the positioning boss 85 and the positioning hole 87, and the positioning boss 86 and the positioning hole 88 constitute base body positioning portions 91 and 92, respectively, wherein the positioning in assembling the first and second base bodies 83 and 84 to each other is carried out by the base body positioning portions 91 and 92. Consequently, the accuracy of assembly of the first and second base bodies 83 and 84 is improved, so that the axes of the shaft supporting portions 35 and 36 provided on the respective base bodies 83 and 84 can be made to coincide with each other. Therefore, the pinion shaft 41, which is supported rotatably by the first and second base bodies 83 and 84 through the bearings 38 and 39, cannot be inclined to a regular position. Further, since the positioning hole 88 has the elongate-hole shape, the assembly of the first and second base bodies 83 and 84 is possible even if each position of the positioning bosses 85 and 86 is deviated to a degree of dimensional tolerance.
Thus, in the opening/closing apparatus 15, the first and second base bodies 83 and 84 to be assembled to each other are provided with the base body positioning portions 91 and 92, the accuracy of assemble of the first and second base bodies 83 and 84 can be improved.
Also, the holding shaft 62 passing through the through hole 48a provided in the guide rail 48 projects from the guide rail 48 and is engaged with the rail positioning hole 93 provided in the first base body 83. That is, the holding shaft 62 has a function as a so-called knock pin for positioning the guide rail 48 with respect to the first base body 83, namely, the holding shaft 62 constitutes the rail positioning portion 94 together with the rail positioning hole 93. Further, a through hole 48b is provided in the guide rail 48 a predetermined distance away from the through hole 48a in the axial direction, wherein the rail positioning boss 95 provided on the first base body 83 is engaged with the through hole 48b. In this way, the holding shaft 62 is engaged with the rail positioning hole 93 and the rail positioning boss 95 is engaged with the through hole 48b, so that the guide rail 48 is positioned with respect to the first base body 83.
As shown in
Thus, the positional relation between the axis of the pinion shaft 41 and the respective positioning portions 91, 92, and 94 is determined depending on the setting of dimensions directed to the same direction by using the axis of the pinion shaft 41 as a reference. Therefore, by using as the minimum value the dimensional tolerance etc. generated in setting each position of the positioning portions 91, 92, and 94, the positions of the respective positioning portions 91, 92, and 94 can be set up accurately. Further, since the axial direction of the guide rail 48 is set to be perpendicular to the straight line L, the position of the rail positioning boss 95 can be set up accurately so that the dimensional tolerance is kept to have the minimum value. Therefore, the installation accuracy of the respective base bodies 83 and 84 and the accuracy of the installation of the guide rail 48 onto the first base body 83 can be improved.
As described above, in the opening/closing apparatus 15, the axis of the pinion shaft 41, the base body positioning portion 91, and the rail positioning portion 94 are disposed on the same straight line, and the axial direction of the guide rail 48 is set up to be perpendicular to the straight line L passing the axis of the pinion shaft 41, the base body positioning portions 91 and 92, and the rail positioning portion 94. Therefore, the installation accuracy of each member can be improved. Further, since the installation accuracy of each member is improved, the verticality of the pinion shaft 41 and the dimensional accuracy such as the interval between the rack 45 and the pinion 46 are improved, so that the operation of the opening/closing apparatus 15 can be made smooth.
Needless to say, the present invention is not limited to the above-mentioned embodiment and can be variously altered and modified without departing from the gist thereof. For example, in the above-described embodiment, the opening/closing member is detailed as the back door 12 openably/closably mounted vertically on the rear end of the vehicle 11. However, the present invention is not limited to this example and may be applied to another opening/closing member such as a laterally opening door.
Also, in the above-described embodiment, the actuator unit 16 is fixed to the interior of the pillar of the vehicle 11. However, the present invention is not limited to this example and may be disposed inside the roof 13 of the vehicle 11. In this case, the rack 45 is reciprocably provided substantially horizontally to the vehicle 11.
Further, in the above-described embodiment, the sliding member is not limited to a member in which the engaging portion 55 is engaged with the engaging hole 56 provided in the slide block 47. For example, the sliding member may be a member having, as shown in
Additionally, in the above-described embodiment, a pair of the sliding members 53a and 53b are used as sliding members. However, the present invention is not limited to this example, and, for example, as shown in
Further, in the above-described embodiment, one holding member 61 opposing the pinion shaft 41 is provided. However, the present invention is not limited to this example, and, for example, as shown in
Note that, members in
Additionally, the axial direction of the guide rail needs to be substantially at right angle to the straight line L, and further the axes of the respective positioning portions 91, 92, and 94 and the axis of the pinion shaft 41 need to be located substantially on the same straight line.
Number | Date | Country | Kind |
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2003-350566 | Oct 2003 | JP | national |
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6378392 | Dombrowski et al. | Apr 2002 | B1 |
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Number | Date | Country |
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2000-264067 | Sep 2000 | JP |
2001-253241 | Sep 2001 | JP |
2001-280000 | Oct 2001 | JP |
2001280000 | Oct 2001 | JP |
Number | Date | Country | |
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20050076571 A1 | Apr 2005 | US |