Patent Grant
6955079
1. Field of the Invention
The present invention relates to a detector for detecting a movable body such as an automatic door catching a foreign material, to a foreign material detector for a sliding door which detects a foreign material caught between a door panel and a vehicle body of a vehicle and a detecting method thereof.
2. Description of the Related Art
Among vehicles referred to as recreation vehicles and generally including wagons and vans, there is a vehicle in which a so-called automatic sliding door device, which allows a door panel to slide forward and backward along a side wall portion of a vehicle body by means of a driving force of a motor and opens and closes an entrance formed in the side wall of the vehicle body, is adopted. In this device, by operating an operation switch provided in the vicinity of a driver's seat and at a predetermined location of back seats, the motor is driven and the door panel is moved.
Further, among this kind of automatic sliding door devices, there is an automatic sliding door device which includes a foreign material detector which detects a state of catching a foreign material existing between a door panel and a vehicle body at the time of closing movement of the door panel.
The foreign material detector applied to the above-described automatic sliding door device includes a pressure sensor which is elongated along a front end portion (i.e., an end portion of a closing movement direction side) of a door panel and in which a plurality of wires are disposed inside a hollow outer cover portion thereof along a longitudinal direction of the pressure sensor. This pressure sensor is structured such that, when the outer cover portion receives a pressing force and is elastically deformed, the wires disposed within the outer cover portion are bent and come into contact with each other, accompanied with the elastic deformation of the outer cover portion. Then, by detecting a change in an electric resistance at the time that the wires came into contact with each other, for example, a fact that the pressing force acted upon the outer cover portion, i.e., a fact that a foreign material abutted the front end portion of the door panel which moves in a closing direction, is detected.
Meanwhile, among vehicles to which the above-described sliding doors are applied, there is a vehicle, in which a so-called “vent hem structure” in which a front end portion of a door panel is formed in a plate form which is sufficiently thinner than a main body portion of the door panel, is adopted. In this structure, when the door panel closes an entrance, the front end portion of this door panel is located at a vehicle interior side of a vehicle body (a side wall of the vehicle), and also opposes the vehicle body along a substantial right and left direction of the vehicle (a substantial vehicle transverse direction).
In a case in which the vent hem structure is adopted in a vehicle, the front end portion of the door panel opposes the vehicle body at a vehicle interior side in a closed state of the door panel. Thus, if a coating which is similar to that coated on the vehicle body is applied up to a tip end of the door panel, even in a case in which a gap is formed between the entrance and the door panel, the coating applied to the front end portion of the door panel can be seen in an inner side thereof. This feature contributes to improve an appearance quality of a vehicle.
In a vehicle in which such a vent hem structure is adopted, the front end portion of the door panel faces the vehicle body at the vehicle interior side in the closed state of the door panel, and the door panel moves toward a vehicle front and then shifts toward a vehicle interior side immediately before the door panel closes up the entrance. This feature is different from that of a structure, in which a door panel simply moves in a substantial longitudinal direction of a vehicle.
Therefore, concerning the above-described foreign material detector, improvement in a detection performance has been longed with respect to catching a foreign material accommodating with the above-described vent hem structure.
An object of the present invention is to provide a foreign material detector and a foreign material detector for a sliding door, each of which can reliably detect catching of a foreign material occurred between a movable body and a closed body in a structure in which an end portion of a closing movement direction side of the movable body is positioned at a lateral side of the closed body in a state in which the movable body such as a door panel closes the closed body such as a vehicle body in which an entrance is formed.
A first aspect of the present invention is a foreign material detector for detecting a foreign material caught between a closing movement side end portion of a movable body and a closed body, which is applied to an opening and closing mechanism in which the movable body moves in the closing movement direction with respect to the closed body, the movable body moves toward a closing direction which is leaned with respect to the closing movement direction immediately before the closing movement direction side end portion of the movable body reaches a closing movement end point located substantially at an orthogonal direction lateral side of the closed body with respect to the closing movement direction, and the movable body thus closes a gate provided between the movable body and the closed body along the closing movement direction, comprising: a pressure sensor, which is directly or indirectly mounted to the movable body at lateral side of the movable body along a substantial orthogonal direction with respect to the closing movement direction, moves with the movable body, and detects a pressed reaction force effected from the foreign material when it presses the foreign material.
In an opening and closing mechanism with the above-described structure in which the foreign material detector is adopted, a movable body moves in a closing direction which is leaned with respect to the closing movement direction at a point immediately before an end point of the closing movement of the movable body, a gate between the movable body and a closed body is thereby closed by the movable body.
Therefore, in a case in which a foreign material was caught between the movable body and the closed body in this opening and closing mechanism, an orientation of a pressing force applied from the movable body to the foreign material and that of a pressed reaction force effected from the foreign material corresponding to the pressing force are tilted with respect to the closing movement direction.
Moreover, in a state in which the movable body reached at the end point of the closing movement thereof, a closing movement direction side end portion of the movable body is positioned substantially at an orthogonal direction lateral side with respect to the closing movement direction of the closed body. Therefore, when the foreign material is caught between the movable body and the closed body, the pressing force applied from the movable body and along the closing direction acts not only toward a direction in which the foreign material is compressed but toward a direction in which the foreign material is sheared.
Here, in the present foreign material detector, though the pressure sensor is integrally provided with the movable boy, a mounting position of the pressure sensor with respect to the movable body is at a substantial orthogonal direction lateral side with respect to the closing movement direction of the movable body so that the pressed reaction force effected from the foreign material which is in a caught state is reliably detected by the pressure sensor, in comparison to a case in which the pressure sensor is simply provided at a closing movement direction side end portion of the movable body. Therefore, the state of catching the foreign material can reliably be detected even in the opening and closing mechanism as described above.
It should be noted that an aspect of the gate is not limited at all in the present invention. In other words, the gate may simply be a gap between the movable body and the closed body, or may substantially be an opening formed in the closed body.
It should further be noted that a movement of the closed body is not limited at all in the present invention. In other words, a structure in which the closed body moves as well as the movable body, when the movable body opens/closes the gate, may also be applied.
Preferably, the present invention is characterized by the pressure sensor comprising: an outer cover portion which is hollow and formed of a synthetic resin which is elastically deformable by the pressed reaction force; a plurality of wires which is provided in an inner side of the outer cover portion and come into contact to connect to each other due to the elastic deformation of the outer cover portion; and a retaining portion which has a rigidity higher than the outer cover portion and retains the outer cover portion at a side opposite to the closing movement direction or the closing direction of the outer cover portion.
In the foreign material detector with the above-described structure, when the hollow outer cover portion forming the pressure sensor is elastically deformed by the pressed reaction force effected from the foreign material, the plurality of wires provided within the outer cover portion come into contact to connect to each other due to the elastic deformation of the outer cover portion. The state of catching the foreign material can be detected by detecting this electrical conduction.
Here, though the outer cover portion is retained by the retaining portion from the direction opposite to the closing movement or the closing direction of the movable body, the pressure sensor retained by the retaining portion is positioned at a closing movement direction side or the closing direction side of the closing movement direction side end portion of the movable body. Therefore, the foreign material does not abut the closing movement direction side end portion of the movable body before it elastically deforms the outer cover portion, the foreign material can thus be reliably detected.
More preferably, the present invention is characterized in that the pressure sensor is mounted to the movable body in a state in which a gap is formed between the pressure sensor and the closing movement direction side end portion of the movable body.
In the foreign material detector with the above-described structure, since a gap is formed between the pressure sensor and the closing movement direction side end portion of the movable body, the elastic deformation of the outer cover portion due to the pressed reaction force effected from the foreign material is not prevented by an interference of the closing movement direction side end portion of the movable body. Therefore, it is ensured that the outer cover portion is elastically deformed and electrodes of the wires provided within the outer cover portion thus come into contact to connect to each other. Thus, reliability of the present foreign material detector increases.
Preferably, the present invention is characterized by comprising: a supporting device which is integrally mounted to the movable body at a side opposite to the closing movement direction side of the pressure sensor; and a retainer in which a groove portion into which the supporting device can enter from the side opposite to the closing movement direction and which includes a nipping portion which nips a tip end portion of the supporting device which entered the groove portion from both sides thereof, while retaining the pressure sensor.
In the foreign material detector with the above-described structure, the supporting device enters the groove portion formed in the retainer which retains the pressure sensor, the tip end portion of the supporting device is nipped from both sides thereof by the nipping portion of the retainer, and this supporting device is further integrally mounted to the movable body, the pressure sensor is thereby indirectly mounted to the movable body and supported.
Here, as described above, the tip end portion of the supporting device entered into the groove portion is nipped from both sides thereof by the nipping portion. Therefore, the nipping portion interferes with the tip end portion of the supporting device and thereby regulates displacement of the supporting device.
The relative displacement between the supporting device and the retainer due to the above-described external forces can thereby be prevented and the pressure sensor can always be retained at a preset position, so that a constant detection performance can be continually maintained. Moreover, there is a sufficient possibility that the above-described external forces arises at the time of mounting the pressure-sensor and at the time of joining the retainer to the supporting device. However, since a change in a position of the pressure sensor caused by such external forces is prevented, the external forces can sufficiently be applied to the pressure sensor and the retainer, reliable mounting can be carried out, while the mounting can be carried out with no concern about the external force, which improves workability.
A second aspect of the present invention is a foreign material detector for a sliding door which is applied to a sliding door device, in which a door panel performs an opening and closing movement in a vehicle longitudinal direction, the door panel moves toward a closing direction which is leaned with respect to the vehicle longitudinal direction immediately before a closing movement direction side end portion of the door panel reaches a closing movement end point located at a lateral side of a vehicle side wall along a substantial orthogonal direction with respect to a closing movement direction, a gate provided in the vehicle side wall is thereby closed, comprising: a pressure sensor, which is provided at a position offsetting toward a closing movement side of a tip end portion of the door panel and toward a vehicle right and left direction lateral side, along a vertical direction of the door panel, and detects catching of a foreign material occurred between the tip end portion of the door panel and the vehicle side wall.
In the sliding door in which the foreign material detector for a sliding door with the above-described structure is applied, the gate provided in the side wall of the vehicle is opened and closed by the door panel performing an opening and closing movement along a longitudinal direction of the vehicle. However, at a point immediately before the gate is closed (i.e., at a point immediately before the door panel reaches an end point of the closing movement thereof), the door panel moves toward the closing direction which is leaned with respect to the vehicle longitudinal direction. Therefore, when the door panel closes the gate, the tip end portion of the door panel (specifically, the closing movement direction side end portion of the door panel) is positioned at a lateral side of the side wall of the vehicle along the vehicle transverse direction.
On the other hand, in a case in which the foreign material is caught between the door panel and the side wall of the vehicle when the door panel closes the gate, the door panel applies a pressing force to the foreign material, and the pressed reaction force acted from the foreign material at the time is applied to the door panel.
Meanwhile, as described above, in a structure in which the door panel is moved toward the closing direction which is leaned with respect to the vehicle longitudinal direction at a point immediately before the gate is closed, orientations of the above-described pressing force and pressed reaction force are leaned with respect to the vehicle longitudinal direction.
Moreover, in a state in which the door panel gate is closed, the tip end portion of the door panel is positioned at the lateral side of the side wall of the vehicle along the vehicle transverse direction. Therefore, when the foreign material is caught between the door panel and the side wall, the pressing force applied from the door panel to the foreign material may act not only in a direction in which the foreign material is compressed along the closing direction, but also in a direction in which the foreign material is sheared.
Here, in the present invention (the foreign material detector for a sliding door), the pressure sensor is provided at the closing movement side of the tip end portion of the door panel and at a position displaced toward a vehicle right and left direction (vehicle transverse direction) lateral side of the tip end portion of the door panel. Therefore, the pressed reaction force effected from the foreign material which is in a caught state reliably acts upon the pressure sensor, compared with a case in which the pressure sensor is simply provided at the tip end portion of the door panel. Accordingly, the state of catching the foreign material can be reliably detected, even in the sliding door as described above.
Preferably, in the foreign material detector according to the second aspect of the present invention, the closing movement direction of the door panel is set to a direction which is leaned toward a vehicle transverse direction interior side with respect to the vehicle longitudinal direction, while the pressure sensor is provided at a position which is displaced from the tip end portion of the door panel toward the interior side of the vehicle.
In the foreign material detector for a sliding door with the above-described structure, the closing direction of the door panel is a direction which is leaned toward the vehicle transverse direction interior side with respect to the vehicle longitudinal direction, and the pressure sensor is displaced from the tip end portion of the door panel toward the interior side of the vehicle. Therefore, in a case in which the door panel is about to insert the foreign material between the door panel and the side wall of the vehicle, the foreign material comes into contact with the pressure sensor prior to the tip end portion of the door panel coming into contact therewith, so that the state of catching the foreign material can be readily and reliably detected.
More preferably, the foreign material detector for a sliding door according to the second aspect of the present invention is characterized by a pressure sensor comprising: an outer cover portion which is hollow and formed of a synthetic resin material which is elastically deformable due to the pressed reaction force; a plurality of wires which are provided in an inner side of the outer cover portion and come into contact to connect to each other due to the elastic deformation of the outer cover portion; and a retaining portion which has a rigidity higher than the outer cover portion and retains the outer cover portion at a side opposite to the closing movement direction or the closing direction of the outer cover portion.
In the foreign material detector for a sliding door with the above-described structure, when the outer cover portion which is hollow and forms the pressure sensor is elastically deformed by the pressed reaction force effected from the foreign material, electrodes of the plurality of wires provided within the outer cover portion come into contact to connect to each other due to the elastic deformation of the outer cover portion. By detecting this electrical conduction, the state of catching the foreign material can be detected.
Here, though the outer cover portion is retained by the retaining portion from the direction opposite to the closing movement or the closing direction, the pressure sensor held by the retaining portion is positioned at the closing movement direction side or closing direction side of the closing movement direction side end portion of the door panel. Thus, the pressure-sensor does not abut the closing movement direction side end portion of the door panel before the foreign material elastically deforms the outer cover portion, so that reliable detection of the foreign material is enabled.
More preferably, in the foreign material detector for a sliding door according to the second aspect of the present invention, the pressure sensor is mounted to the door panel in a state in which a gap is formed between the pressure sensor and the tip end portion of the door panel.
In the foreign material detector for a sliding door with the above-described structure, since a gap is formed between the pressure sensor and the tip end portion of the door panel, the elastic deformation of the outer cover portion due to the pressed reaction force effected from the foreign material is not prevented by the interference of the closing movement direction side end portion of the door panel. Accordingly, it is ensured that the outer cover portion is elastically deformed by the pressed reaction force effected from the foreign material, and the electrodes provided within the outer cover portion come into contact to connect to each other. Thus, reliability of the present foreign material detector for a sliding door increases.
More preferably, the foreign material detector for a sliding door according to the second aspect of the present invention is characterized by including: a supporting device which is integrally mounted to the door panel at a side opposite to the closing movement direction of the pressure sensor; and a retainer in which a groove portion into which the supporting device can enter from a side opposite to the closing movement direction is formed and which comprises a nipping portion which nips a tip end portion of the supporting device entered into the groove portion from both sides thereof, while retaining the pressure sensor.
In the foreign material detector for a sliding door with the above-described structure, the supporting device enters the groove portion formed in the retainer which retains the pressure sensor, the tip end portion of the supporting device is nipped from both sides thereof by the nipping portion of the retainer, the supporting device is further integrally mounted to the door panel, the pressure sensor is thereby indirectly mounted to the door panel and supported.
Here, as described above, the tip end portion of the supporting device entered into the groove portion is nipped from both sides thereof by the nipping portion. Therefore, the nipping portion interferes with the tip end portion of the supporting device, and displacement of the supporting device is regulated.
Relative displacement between the supporting device and the retainer due to the above-described external forces can thereby be prevented, and the pressure sensor can always be retained at a preset position. Therefore, a constant detection performance can be continually maintained. Moreover, there is a sufficient possibility that the external forces as described above arise at the time of mounting the pressure sensor and at the time of joining the retainer to the supporting device. However, since a change in a position of the pressure-sensor due to such an external force is prevented, sufficient external forces can be applied to the pressure sensor and the retainer and reliable mounting can thus be carried out, while it is not necessary to concern about the external force at the time of mounting, which improves workability.
A third aspect of the present invention is a method for detecting a foreign material caught in a sliding door device, in which a door panel performs an opening and closing movement in a vehicle longitudinal direction, the door panel moves toward a closing direction which is leaned with respect to the vehicle longitudinal direction immediately before a closing movement direction side end portion of the door panel reaches a closing movement end point located at a lateral side of a vehicle side wall along a substantial orthogonal direction with respect to a closing movement direction, a gate provided in the vehicle side wall is thereby closed; the method comprising a step of: detecting a foreign material which intersects the closing movement direction of the door panel and impedes closing of the door panel by a pressure sensor extending at the closing movement direction side of a tip end portion of the door panel and mounted to an outside of the door panel.
<Structure of the automatic sliding door device 16>
As shown in
A reduction gear 32 is provided at a lateral side of the sliding door motor 28. This reduction gear 32 contains a plurality of gears which includes a gear engaged with an output axis of the sliding door motor 28. Rotation of the sliding door motor 28 is transmitted, while being decelerated, by these gears externally to a driving pulley 30, this driving pulley 30 is thereby rotated.
The driving pulley 30 is rotatable around an axis provided such that an axial direction thereof is substantially a vehicle vertical direction. An endless belt 36 is wound around the driving pulley 30 and a plurality of driven pulleys 34 provided spacing apart from this driving pulley 30. When the sliding door motor 28 starts driving and the driving pulley 30 is rotated, the endless belt 36 is followingly rotated.
As shown in
As shown in
The door panel with the above-described structure is formed corresponding to an entrance 58 (see
As described above, the coating which is the same as that applied to the side wall 22 is applied to the vehicle transverse direction outer surface of the hem 52. Therefore, even when a gap S1 is produced between an inner peripheral portion of the entrance 58 and a portion of the door panel 18 located substantially at a vehicle rear side of the hem 52, the coating coated on the hem 52 which is the same as that applied to the side wall 22 can be seen. Accordingly, deterioration in appearance quality caused by such a gap S1 can be suppressed or otherwise be prevented.
On the other hand, as illustrated in
Meanwhile, as shown in
On the other hand, as shown in
A base end portion of the upper arm 70 is secured in the vicinity of an upper end portion of the inner panel 54 by a fastening device such as bolts (illustration thereof is omitted). The movement of the door panel 18 toward the substantial vehicle transverse direction exterior side is restricted by the movement of the roller 72 toward the substantial vehicle transverse direction exterior side being restricted by the pair of side wall portions 74. Further, a front end side of the upper rail 68 is leaned substantially toward the vehicle transverse direction interior side as well as the front end portion of the center rail 46. When the rollers 62 are guided by the side wall portion 66 at the front end side of the center rail 46, the roller 72 is guided by the upper rail 68 at the front end side of the upper rail 68.
As shown in
A tip end side of the lower arm 80 enters an inner side of the lower rail 76. A roller 82, an axial direction of which is substantially along the vehicle transverse direction and which rotates around an axis thereof, and a roller 84, the axial direction of which is substantially along the vertical direction of the vehicle 14 and which rotates around an axis thereof, are each axially supported at a tip end of the lower arm 80. An outer peripheral portion of the roller 82 abuts a lower wall portion 86 of the lower rail 76 and the roller 82 rolls on the lower wall portion 86.
On the other hand, the roller 84 enters inside a guide rail 88 having a U-shaped cross-section opened downwardly. The guide rail 88 is secured to an upper wall portion of the lower rail 76. An outer peripheral portion of the roller 82 abuts one of a pair of the side wall portions located substantially at the vehicle transverse direction exterior side, between the pair of side wall portions provided substantially along the vehicle transverse direction facing each other. The roller 82 rolls in a state in which it abuts one of the side wall portions, while the displacement thereof toward the substantial vehicle transverse direction exterior side is restricted by the side wall portion located substantially at the vehicle transverse direction exterior side. Further, a front end side of the guide rail 88 is also leaned substantially toward the vehicle transverse direction interior side as well as the front end side of the center rail 46. When the roller 60 is guided by the side wall portion 66 at the front end side of the center rail 46, the roller 84 is guided by the side wall portion at the front end side of the guide rail 88.
In other words, the door panel 18 is slidably mounted to the vehicle body 20 on a track which is substantially along the longitudinal direction of the vehicle 14 through the rollers 62 of the center arm 50, the roller 72 of the upper arm 70, and the roller 84 of the lower arm 80. By driving the sliding door motor 28 of the sliding door actuator 24 normally or reversely, the sliding door motor 28 slides toward the back or the front of the vehicle 14 to open and close the entrance 58.
As illustrated in a block diagram in
Further, the automatic sliding door drive 16 includes a location detector 100 which detects the sliding amount of the door panel 18 by counting a revolution of an output axis of the sliding door motor 28.
As illustrated in
<Structure of a foreign material detector 10>
Next, a structure of the foreign material detector 10 will be described.
As shown in
Further, a plurality of wires 128, 130, 132, and 134, each of which has an electrode coated with a conductive rubber and is formed by twisting conductive thin wires such as copper wires together to an elongated cord with a flexibility, are provided in an inner side of the outer cover portion 124. As shown in
Further, as illustrated in a circuit diagram in
Further, longitudinal direction one end portions of a pair of wires 142, 144 of a lead wire 140 are respectively accommodated inside the connector 136 and fixed to a terminal provided within the connector 136. Each of the longitudinal direction one end portions of the above-described wires 128, 134 which are the other of the end portions respectively conducted with the wire 132 or the wire 130 is secured to the terminal to which these wires 142, 144 are respectively fixed. Accordingly, the wire 142 and the wire 128 are electrically connected, and the wire 144 and the wire 134 are electrically connected.
The wire 142 is directly or indirectly connected to the battery 26 through other connecting members (the wire 142 and the battery 26 are directly connected in the circuit diagram in
As illustrated in
As shown in
The protector 148 includes a recessed portion 150 which has a recessed shape and forms an accommodating portion opened toward the front side of the vehicle 14, and a flexible portion 152 which has a recessed shape and forms an accommodating portion opened toward the rear side of the vehicle 14. The recessed portion 150 is formed of a synthetic resin material or a rubber material having a rigidity which is equivalent to or lower than that of the outer cover portion 124. In contrast, the flexible portion 152 is formed of a synthetic resin material or a rubber material having a rigidity which is lower than that of the recessed portion 150.
The recessed portion 150 and the flexible portion 152 are integrally connected in a state in which the opening directions thereof oppose to each other, the recessed portion 150 and the flexible portion 152 thereby forms a tubular shape on the whole. A catching hole 158 is provided in an inner side of the recessed portion 150 and the flexible portion 152. At a vehicle interior side of a vehicle transverse direction intermediate portion of the catching hole 158, a radius of curvature of an inner peripheral portion of the recessed portion 150 and that of an inner peripheral portion of the flexible portion 152 are nearly equal to a radius of curvature of an outer peripheral portion of the above-described outer cover portion 124. At a vehicle exterior side of the intermediate portion of the catching hole 158, a radius of curvature of the inner peripheral portion of the recessed portion 150 and that of the inner peripheral portion of the flexible portion 152 are larger than a radius of curvature of the outer peripheral portion of the outer cover portion 124.
Therefore, the catching hole 158 generally does not have a circular cross-section and has a substantially oval or elliptical cross-section. At the vehicle interior side of the vehicle transverse direction intermediate portion of the catching hole 158, the outer peripheral portion of the outer cover portion 124 abuts the inner peripheral portion of the catching hole 158 and is nipped by the elasticity of both the recessed portion 150 and the flexible portion 152. At the vehicle exterior side of the vehicle transverse direction intermediate portion of the catching hole 158, a gap S2 is formed between the inner peripheral portion of the catching hole 158 and the outer peripheral portion of the outer cover portion 124.
This gap S2 reduces an interference from the inner peripheral portion of the catching hole 158 (i.e., from the recessed portion 150 and the flexible portion 152) against the outer cover portion 124 subjected to an external force from a direction tilted toward the vehicle transverse direction interior side with respect to the vehicle front side and about to elastically deform such that the portion 124 stretches toward the vehicle exterior side of the vehicle transverse direction intermediate portion of the catching hole 158. Therefore, the outer cover portion 124 can be elastically deformed readily and reliably by the external force effected from the direction tilted toward the vehicle transverse direction interior side with respect to the vehicle front side.
Further, as illustrated in
On the other hand, at a side of the recessed portion 150 where the recessed portion 150 leaned substantially toward the vehicle transverse direction inner side with respect to the substantial vehicle rear, a joining portion 160 is continuously formed from the outer peripheral portion of the recessed portion 150 (a surface facing the recessed portion 150). Further, at a side of this joining portion 160 where the joining portion 160 leaned substantially toward the vehicle transverse direction interior side with respect to the substantial vehicle rear, a mounting portion 154 which serves as a retainer is continuously formed from the joining portion 160. The joining portion 160, as well as the mounting portion 154, is formed of a material which is the same as a synthetic resin material or a rubber material forming the recessed portion 150.
Further, mounting grooves 156 are formed in the mounting portion 154. The mounting grooves 156 are formed in the mounting portion 154 so as to be displaced substantially toward the vehicle transverse direction interior side of the catching hole 158 and opened toward the rear side of the vehicle 14, while being formed substantially in a uniform manner and along longitudinal directions of the recessed portion 150 and the flexible portion 152. A bracket 170 which serves as a supporting device enters an inner side of the mounting grooves 156. The bracket 170 is an elongated plate material disposed along the protector 148 and is bent substantially in a crank form at a transverse direction intermediate portion thereof. Further, a transverse direction one end side of the bracket 170 enters the mounting grooves 156, while the other end side thereof is integrally secured to the inner panel 54 of the door panel 18 by fastening devices such as bolts and rivets, welding or the like.
As illustrated in
As described above, the recessed portion 150, the joining portion 160, and the mounting portion 154 are formed such that the recessed portion 150 is positioned at the vehicle transverse direction exterior side of the joining portion 160 and the joining portion 160 is positioned at the vehicle transverse direction interior side of the mounting portion 154. Moreover, the mounting grooves 156 and the interference groove 164 are located substantially at the vehicle transverse direction interior side of the catching hole 158, as illustrated in FIG. 1.
In other words, in the present embodiment, the pressure sensor 120 is substantially provided at the vehicle interior side of the hem 52, offsetting toward the vehicle front side, while the pressure sensor 120 is substantially provided offsetting toward the vehicle exterior side of the bracket 170 which indirectly supports the pressure sensor 120. The protector 148 is thus provided not only with a rigidity against an external force effected substantially from the vehicle front side, but also with a high rigidity against an external force effected substantially from the vehicle transverse direction exterior side with respect to the substantial vehicle front. Therefore, in a case in which external forces acts on the foreign material detector 10 from these directions, the joining portion 160, the mounting portion 154, as well as the bracket 170, reliably support the outer cover portion 124.
<Operations of the present embodiment at the time of catching a foreign material>
Next, upon describing basic operations and effects of the present embodiment at the time of catching a foreign material, a description of specific operations thereof will be given.
In the present embodiment, if the operation switch 98 is operated to close the door panel 18 in a state in which the door panel 18 forming the entrance 58 is opened, the computer 96 operates the sliding door driver 94 comprising the sliding door actuator 24, the sliding door driver 94 allows the sliding door motor 28 to drive, and the door panel 18 is thereby slid toward the front side of the vehicle 14 (i.e., “the closing movement direction” side) through the endless belt 36 and the center arm 50.
If a foreign material exists on a sliding track of the door panel 18 when the door panel 18 slides forward and the entrance (gate) 58 is closed, the closing movement direction side end (front end) of the door panel 18 abuts the foreign material and presses the foreign material. As the protector 148 and the outer cover portion 124 are elastically deformed by a reaction force effected from the foreign material at this time, the wire 128 or the wire 132 provided within the outer cover portion 124 comes into contact and connects to the wire 130 or the wire 134, and the circuit is short-circuited.
As described above, the electric current flowing in the electric circuit which include the wires 128-134 (see
Meanwhile, as described above, in the automatic sliding door device (opening and closing mechanism) 16 of the vehicle 14, up to the point immediately before the door panel (movable body) 18 closes up the entrance (gate) 58, the door panel 18 slides toward the front of the vehicle 14, i.e., in the closing movement direction, along the side wall (closed body) 22. However, from the point immediately before the door panel 18 closes up the entrance 58, the direction of the movement of the door panel 18 is leaned substantially toward the vehicle transverse direction interior side, and the door panel 18 slides in a closing direction shown by arrow A in FIG. 2. In this way, the door panel 18 located at an outer side of the side wall 22 by the time is displaced substantially toward the vehicle interior side, while closing the entrance 58. Further, in a state in which the door panel 18 reaches an end point of its movement where the hem 52 opposes the side wall 22 along the vehicle transverse direction at the vehicle interior side of the side wall 22, an exterior surface of the outer panel 56 substantially becomes coplaner with an exterior surface of the side wall 22.
Here, a pattern of the door panel 18 catching a foreign material in a state in which the door panel 18 is slid in the closing direction which is leaned toward the transverse direction interior side with respect to the substantial vehicle front as described above, will be described, hereinafter.
In a first catching pattern described in
In the pattern above, the pressing force from the door panel 18 attempts to pivotably rotate the substantial vehicle front side of the foreign material 180 toward the vehicle transverse direction exterior side (i.e., in the direction of arrow C in
In the present embodiment, as described above, the protector 148 has a high rigidity against the external force applied substantially from the vehicle transverse direction external side with respect to the substantial vehicle front, and, in a case in which the external force is applied from the direction, the joining portion 160, the mounting portion 154, and the bracket 170 can reliably support the outer cover portion 124. Accordingly, it is ensured that the outer cover portion 124 can be elastically deformed by the pressed reaction force from the foreign material 180 and the pressed reaction force can be detected.
Further, since a gap S3 is formed between the recessed portion 150 and the hem 52 as described above, the elastic deformation of the flexible portion 152 and the recessed portion 150 due to the reaction force from the foreign material 180 is not prevented by the hem 52, it is thus ensured that the outer cover portion 124 is elastically deformed by the pressed reaction force from the foreign material 180.
As described above, in the present embodiment, the foreign material 180 can be detected by the pressure sensor 120 even in a case of the above-described first catching pattern.
Next, a description of a second catching pattern will be given.
Differing from the first pattern described above, the second catching pattern illustrated in
In this second catching pattern, an orientation of the pressed reaction force is leaned substantially toward the vehicle rearward and toward the vehicle transverse direction exterior side as illustrated by arrow D in
As described above, in the present embodiment, the foreign material 180 can be detected by the pressure sensor 120 even in a case of the above-described second catching pattern.
Nest, a description of a third catching pattern will be given.
Differing from the first pattern described above, the third catching pattern illustrated in
In this third catching pattern, as shown in
<Operations of the present embodiment at the time of assembly or the like>
Next, operations and effects in the present embodiment will be described in terms of assembly.
In the foreign material detector 10 of the present invention, the protector 148, in which the pressure sensor 120 is caught into the catching hole 158, is assembled such that the transverse direction one end side of the bracket 170 which is the other end side of the bracket 170 being assembled to the door panel 18 enters the mounting grooves 156 and the interference groove 164 of the mounting portion 154.
At the time of attaching the protector 148 to the bracket 170, the protector 148 is pressed substantially from the front side of the vehicle until the bracket 170 abuts a bottom portion of the interference groove 164. Here, in a case in which this pressing force is in excess, the one end side of the bracket 170 abutted the bottom portion of the interference groove 164 relatively attempts to escape toward a transverse direction either side of the interference groove 164. Provisionally, in a case in which the bracket 170 is displaced in the interference groove 164 and escaped toward the transverse direction either side of the interference groove 164, a mounting position of the pressure sensor 120 with respect to the bracket 170 is consequently displaced.
However, differing from the mounting grooves 156, an opening width dimension of the interference groove 164 is substantially equal to or smaller than the plate thickness of the bracket 170. Therefore, when the bracket 170 is about to displace within the interference groove 164, the inner wall of the interference groove 164 interferes with the bracket 170 to regulate the displacement of the bracket 170. Accordingly, escaping of the bracket 170 resulted from the above-described pressing force can be prevented or effectively suppressed, and the pressure sensor 120 can be reliably mounted to a preset position.
Incidentally, it is a matter of course that, even though the protector 148 is about to be displaced with respect to the bracket 170 due to the pressed reaction force effected from the foreign material 180, the inner wall of the interference groove 164 interferes with the bracket 170 and regulates the displacement of the bracket 170.
Further, in the respective embodiments described above, the foreign material detector 10 was used for preventing the foreign material 180 from being caught at the door panel 18 in the automatic sliding door device 16 of the vehicle 14. However, the scope of the present invention is not limited to the same.
That is, in a case in which the foreign material detector 10 of the present invention is used for an automatic sliding door device, it is used for automatic sliding door devices employed in any fields, such as a vehicle other than an automobile (e.g., a railway rolling stock), an elevator, and an automatic door and a window of a building or the like.
Further, in the respective embodiments described above, the inner peripheral portion of the entrance 58 (i.e., the side wall 22) which never be moved basically was used as a closed body. However, the closed body may be structured in such a manner that the closed body itself can move. In other words, for example, among the automatic sliding door devices, there is a device structured in such a manner that an entrance or a gate is opened/closed by a pair of door panels sliding in a direction which is reciprocal to each other. The distance between the pair of door panels are ultimately closed by the pair of door panels being respectively moved in a closing direction until an end point of their movement. Therefore, in a case of such a structure, one of the door panels is a movable body, and the other is a closed body.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2001-031430 | Feb 2001 | JP | national |
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| Number | Date | Country | |
|---|---|---|---|
| 20020104373 A1 | Aug 2002 | US |
