This application is based on and claims priority under 35 U.S.C. §119 to Japanese Patent Application No. 2007-282211, filed on Oct. 30, 2007, the entire content of which is incorporated herein by reference.
This invention generally relates to an opening and closing member control apparatus for a vehicle.
Various types of vehicle opening and closing member control apparatuses are proposed. For example, according to an opening and closing member control apparatus for a vehicle disclosed in JP9125820 (hereinafter referred to as “Reference 1”), in the cases where the opening and closing member such as a sliding door that can be automatically opened or closed is operated by a user, and the like, an operation of the door is detected, i.e., an opening or closing speed of the door is detected, by a speed sensor. Then, an electromagnetic clutch and a drive motor are powered on the basis of the detection results to thereby electrically assist the opening or closing operation of the door.
In addition, for example, an opening and closing member control apparatus for a vehicle disclosed in JP2001246936A (hereinafter referred to as “Reference 2”) detects an operating force required for opening or closing the opening and closing member such as a door by means of an operating force sensor provided at a door handle. The door opening or closing operation is then assisted in response to the detected operating force.
According to the opening and closing member control apparatus disclosed in Reference 1, the door operation is detected by means of the speed sensor that detects the opening or closing speed of the door so as to supply power to the electromagnetic clutch and the drive motor. Thus, in the cases where the door is stopped between a fully closed position and a fully open position by means of the clutch in the connected state so as to prevent the door from moving by its own weight on a slope, and the like, the door cannot be operated by the user. As a result, the opening or closing speed of the door cannot be detected by the speed sensor. It may be difficult for the door to be electrically opened or closed from such stopped state.
According to the opening and closing member control apparatus disclosed in Reference 2, the operating force of the door handle is detected for assisting the door opening or closing operation in response to the detected operating force. At the time the door is operated via a portion other than the door handle, such operating force is not detectable. Thus, in the cases where the door handle is out of reach when the door is opened, such as a case of a rear hatch, the door handle cannot be operated when the door is stopped in the middle, i.e., stopped between the fully closed state and the fully open state. The opening or closing operation of the door cannot be assisted accordingly.
A need thus exists for an opening and closing member control apparatus for a vehicle which is not susceptible to the drawback mentioned above.
According to an aspect of the present invention, an opening and closing member control apparatus includes a driving device adapted to drive an opening and closing member to open and close an opening portion formed at a vehicle body, a sensor provided at a connecting portion connecting the vehicle body with the opening and closing member, the sensor detecting an opening operation and a closing operation of the opening and closing member, and a drive controlling device controlling the driving device to drive the opening and closing member to open or close the opening portion by determining the opening operation or the closing operation of the opening and closing member based on a detection value of the sensor.
The foregoing and additional features and characteristics of the present invention will become more apparent from the following detailed description considered with reference to the accompanying drawings, wherein:
A first embodiment of an opening and closing member control apparatus for a vehicle will be explained with reference to the attached drawings.
A drive unit 4 serving as driving means is provided at a rear portion of the vehicle body 2 (specifically, an inner panel thereof) via a bracket 5 serving as a connecting portion and made of a metallic plate, for example. As illustrated in
The second end of the rod 9 is connected to the rear hatch 1 at a portion close to a rotational center of the rear hatch 1 (i.e., close to the door hinge) as illustrated in
As illustrated in
In the cases where the rear hatch 1 of the aforementioned structure is opened or closed by a user, and the like from the outside of the vehicle, a strain having a polarity depending on the operating direction of the rear hatch 1 is generated in the stepped portion 5b. According to the present embodiment, a strain gauge 10 serving as a sensor is attached to the stepped portion 5b so as to detect a strain generated in the stepped portion 5b. The strain gauge 10 is arranged in the vicinity of substantially a center portion between the fastening portions 5d and 5e so that the strain gauge 10 can uniformly detect the strains generated in both opening and closing operations of the rear hatch 1.
Specifically, as illustrated in
The rear hatch 1 is equipped with a door handle 11 by means of which the rear hatch 1 is opened from the outside of the vehicle in the cases where the rear hatch 1 is in the fully closed position or in the vicinity thereof. A known closer apparatus 12 is provided at a lower end portion of the rear hatch 1 for the purposes of driving the rear hatch 1 to move to the fully closed position so as to fully engage a striker provided at the vehicle body 2 when the rear hatch 1 is in a so-called half-shut state (i.e., half-latched state).
An electrical structure of the opening and closing member control apparatus according to the first embodiment will be explained with reference to a block diagram illustrated in
An opening and closing control of the rear hatch 1 performed by the ECU 16 will be explained below. The rear hatch 1 is assumed to be stopped at an arbitrary open position, i.e., between the fully open position and the fully closed position, and the electromagnetic clutch 13 is in the connected state to stabilize the arm member 8 relative to the drive unit 4 for the purposes of retaining the position of the rear hatch 1. In such circumstances, when the operating force for opening or closing the rear hatch 1 is applied from the outside of the vehicle by a user to an arbitrary portion of the rear hatch 1, the operating force is transmitted in order from the rear hatch 1 through the rod 9, the arm member 8, the drive unit 4, the bracket 5 and the vehicle body 2 (inner panel). At this time, the strain is generated in the strain gauge 10 attached to the stepped portion 5b of the bracket 5 and is then converted into the electrical signal at the strain gauge 10. The strain gauge 10 outputs the electrical signal to the ECU 16 as a detection value having a polarity depending on the operating direction of the rear hatch 1 by the user. The ECU 16 drives the electromagnetic clutch 13 to the connected state and maintains the connected state of the electromagnetic clutch 13 in response to the detection value. In addition, the ECU 16 controls the electric motor 6 to rotate in a direction depending on the operating direction of the rear hatch 1 by the user. Accordingly, the rear hatch 1 is opened or closed automatically in response to the operating direction of the rear hatch 1. In the cases where it is detected by the position sensor 14 that the rear hatch 1 reaches the fully open position or the vicinity of the fully closed position corresponding to the half-shut (half-latched) position, the ECU 16 drives the electromagnetic clutch 13 to the disconnected state and stops the driving of the electric motor 6. When the rear hatch 1 reaches the vicinity of the fully closed position corresponding to the half-shut (half-latched) position, the closer apparatus 12 is activated to drive the rear hatch 1 to the fully closed position.
According to the aforementioned first embodiment, the following effects may be obtained. (1) The strain gauge 10 is provided at the bracket 5 through which the drive unit 4 is attached to the vehicle body 2. Thus, even when the rear hatch 1 is stopped at any position between the fully closed position and the fully open position, for example, a force applied by a user to an arbitrary portion of the rear hatch 1 for opening or closing the rear hatch 1 is detectable at the bracket 5 (specifically, at the stepped portion 5b thereof). As a result, the opening operation or the closing operation of the rear hatch 1 is determined, i.e., it is determined which direction the rear hatch 1 is operated, on the basis of the detection value of the strain gauge 10 so as to open or close the rear hatch 1 by means of the drive unit 4, thereby starting the automatic open or close operation of the rear hatch 1 in response to the operating direction thereof.
(2) According to the aforementioned first embodiment, the opening operation or the closing operation of the rear hatch 1 is detectable by the strain gauge 10 having an extremely simple structure.
A second embodiment of the opening and closing member control apparatus for a vehicle will be explained with reference to the attached drawings.
The center guide rail 23 is fixed to an exterior surface of the side body 22 on a rear side relative to the opening portion 22a so as to extend in the vehicle longitudinal direction. The upper guide rail 24 is arranged along an upper end of the side body 22 in the vicinity of an upper end of the opening portion 22a and is fixed to the side body 22. The lower guide rail 25 is arranged along a lower end of the side body 22 in the vicinity of a lower end of the opening portion 22a and is fixed to the side body 22.
Guide roller units 26 slidably guided by the respective guide rails 23 to 25 are rotatably supported by the sliding door 21. With the respective guide roller units 26 sliding on the guide rails 23 to 25, the sliding door 21 is slidably operated, being guided by the guide rails 23 to 25 for opening or closing the opening portion 22a. The guide rails 23 to 25 are arranged in parallel with each other. Respective front ends of the guide rails 23 to 25 are bent towards a vehicle interior side for the purpose of guiding the sliding door 21 in such a way that the sliding door 21 and the exterior surface of the side body 22 are positioned on the same plane when the opening portion 22a is closed, i.e., the sliding door 21 is in the fully closed position. When the opening portion 22a is open, the sliding door 21 is positioned, overlapping the exterior surface of the side body 22 on the vehicle rear side relative to the opening portion 22a as illustrated in
As illustrated in
As illustrated in
Next, a power-sliding unit for driving the sliding door 21 to be slidably operated will be explained with reference to
The drive unit 36 is arranged inside of the sliding door 21. Specifically, the drive unit 36 is fixed to a door panel of the sliding door 21 by means of a bracket 36a serving as a connecting portion (see
The cable 37 includes two wires 43 and 44 of which respective one ends engage with the output drum 40. The wires 43 and 44 are wound around the output drum 40. As illustrated in
The pulley mechanism 38 is fixed by means of a base bracket 46 to the base plate 29 of the guide roller unit 26 via screws 47. Specifically, the pulley mechanism 38 includes two guide pulleys 48 and 49 that are rotatably supported by the base bracket 46 via pins 48a and 49a. As illustrated in
An operation of the power-sliding unit will be explained below. As illustrated by a solid line in
On the other hand, in the cases where the output drum 40 is driven to rotate in the other direction by the electric motor 39 that rotates in the rearward direction with the sliding door 21 in the open state, the wire 43 of the cable 47 is reeled onto the output drum 40 while the wire 44 is reeled out from the output drum 40. Accordingly, the guide pulley 49 moves towards the vehicle front side (i.e., leftward direction in
In the cases where the sliding door 21, which is not operated and stopped, is opened from the outside of the vehicle by a user and the like, the wire 43 is pulled in a state where the output drum 40 is locked, for example. A force resulting from the pulling of the wire 43 is transmitted to the drive unit 36 (output drum 40), the bracket 36a through which the output drum 40 is attached to the door panel of the sliding door 21, the front bracket 43b that holds the wire 43, the pulley mechanism 38 (guide pulleys 48 and 49) that guides the wire 43, the guide roller unit 26 (base plate 29), the bracket 27, and the like. As a result, a strain is generated in the front bracket 43b. On the other hand, in the cases where the sliding door 21, which is not operated and stopped, is closed from the outside of the vehicle by a user and the like, the wire 44 is pulled in a state where the output drum 40 is locked, for example. A force resulting from the pulling of the wire 44 is transmitted to the drive unit 36 (output drum 40), the bracket 36a through which the output drum 40 is attached to the door panel of the sliding door 21, the rear bracket 44b that holds the wire 44, the pulley mechanism 38 (guide pulleys 48 and 49) that guides the wire 44, the guide roller unit 26 (base plate 29), the bracket 27, and the like. As a result, a strain is generated in the rear bracket 44b. According to the second embodiment, the strains generated in the brackets 43b and 44b are detected by strain gauges 51 and 52 attached at the brackets 43b and 44b, respectively. The strain gauges 51 and 52 each serve as a sensor.
That is, when the sliding door 21 is opened from the outside, the strain generated in the front bracket 43b is converted into an electrical signal at the strain gauge 51. Likewise, when the sliding door 21 is closed from the outside, the strain generated in the rear bracket 44b is converted into an electrical signal at the strain gauge 52. The opening and closing operations of the sliding door 21 from the outside of the vehicle are detected by the strain gauges 51 and 52, respectively.
An electrical structure of the opening and closing member control apparatus according to the second embodiment will be explained with reference to a block diagram illustrated in
An opening and closing control of the sliding door 21 performed by the ECU 56 will be explained below.
In the cases where the sliding door 21 is not in the fully closed position in S2, it is determined whether or not the operating position of the sliding door 21 when the open/close switch 57 is operated is equal to the fully open position in S3. When it is determined that the sliding door 21 is in the fully open position, a known process for closing the sliding door 21 by the drive unit 36 (i.e., power close operation) is started in S6.
Further, in the cases where the sliding door 21 is not in the fully open position in S3, i.e., the sliding door 21 is in a position between the fully closed position and the fully open position (i.e., intermediate position), it is determined whether or not the sliding door 21 when the open/close switch 57 is operated is in motion in S4. When it is determined that the sliding door 21 is in motion, a process for retaining the sliding door 21 in the intermediate position (i.e., intermediate position retention) is started in S7. On the other hand, when it is determined that the sliding door 21 is not in motion in S4, a known process for opening or closing the sliding door 21 in response to the position thereof at that time is started in S8.
In the cases where an overload equal to a force generated when an obstacle is pinched between the sliding door 21 and the vehicle body is detected in S5 and S6, which is not shown in
Next, the intermediate position retention process will be explained below.
As illustrated in
Next, a difference between a front detection value before time T1, i.e., vFr (T1), and a present front detection value vFr (T) is calculated as a front variation ΔvFr in S15. In the same way, a difference between a rear detection value before time T1, i.e., vRr (T1), and a present rear detection value vRr (T) is calculated as a rear variation ΔvRr in S16. The time T1 is duration from the stop of the electric motor 39 counted up by a timer.
It is determined whether or not the time T1 exceeds a predetermined time t1 in S17. When it is determined that the time T1 does not exceed the predetermined time t1, the time T1 is counted up by the timer in S18. The operation then returns to S13 to repeat the same routine. Accordingly, the time T1 is repeatedly counted up by the timer until the predetermined time t1 is fulfilled. Once the predetermined time t1 is reached, the predetermined time T1 (=t1) is maintained. That is, after the predetermined time t1 is fulfilled, the difference between the front detection value before time T1, i.e., vFr (T1), and the present front detection value vFr (T), and the difference between the rear detection value before time T1, i.e., vRr (T1), and the present rear detection value vRr (T) are calculated in S15 and S16, respectively.
The opening or closing operation of the sliding door 21 is not performed until the predetermined time T1 (=t1) has elapsed according to the processes in S13 to S18. This is to avoid a wrong operation of the sliding door 21 by a calculation of the ΔvFr and ΔvRr in an unstable state of the strain detection as shown in
In the cases where the time T1 exceeds the predetermined time t1 in S17, a time T2 is counted up by a timer in S19 different from that measuring the time T1. It is determined whether or not the time T2 is below a predetermined time t2 in S20. When it is determined that the time T2 is below the predetermined time t2, then it is determined whether or not an absolute value (i.e., magnitude) of the front variation ΔvFr is below a predetermined value (i.e., threshold value) S1 and whether or not an absolute value (i.e., magnitude) of the rear variation ΔvRr is below a predetermined value (i.e., threshold value) S2 in S21.
When it is determined that the absolute value of the front variation ΔvFr is below the predetermined value S1 and the absolute value of the rear variation ΔvRr is below the predetermined value S2, the operation returns to S13 to repeat the same routine. On the other hand, when it is determined that the absolute value of the front variation ΔvFr is not below the predetermined value S1 or the absolute value of the rear variation ΔvRr is not below the predetermined value S2, the time T2 counted up by the timer is reset once in S22. The operation returns to S13 to repeat the same routine.
According to the present embodiment, it is confirmed in S13 to 17 and S19 to S22 that the state where the absolute value of the front variation ΔvFr is below the predetermined value S1 and the absolute value of the rear variation ΔvRr is below the predetermined value S2 is continued for the predetermined time t2. This is to verify that the variations ΔvFr and ΔvRr fall within a predetermined range and thus are stable, i.e., the load of the sliding door 21 is stable.
When the time T2 is not below the predetermined time t2 in S20, i.e., the time T2 is equal to or greater than the predetermined time t2, the stabilization of the load of the sliding door 21 is verified. Thus, as illustrated in
A difference Δv between a difference of the latest front detection value vFr and the front reference value KvFr, i.e., vFr−KvFr, and a difference of the latest rear detection value vRr and the rear reference value KvRr, i.e., vRr−KvRr, is calculated in S27. Because the electromagnetic clutch 53 is in the connected state so as to retain the sliding door 21 in the intermediate position, the strain generated in the front bracket 43b increases when the sliding door 21 is opened, thereby increasing the front detection value vFr. On the other hand, the strain generated in the rear bracket 44b increases when the sliding door 21 is closed, thereby increasing the rear detection value vRr. Accordingly, the difference Δv is made larger in positive number when the strain generated in the front bracket 43b is larger along with the opening operation of the sliding door 21. In addition, the difference Δv is made larger in negative number when the strain generated in the rear bracket 44b is larger along with the closing operation of the sliding door 21.
It is determined whether or not the difference Δv exceeds a predetermined value S3 (>0) in S28. When it is determined that the difference Δv exceeds the predetermined value S3 and thus the sliding door 21 is determined to be opened, the drive unit 36 starts to assist the opening operation of the sliding door 21 in S30. On the other hand, when it is determined that the difference Δv does not exceed the predetermined value S3, then it is determined whether or not the difference Δv is below a predetermined value S4 (<0) in S29. When it is determined that the difference Δv is below the predetermined value S4 and thus the sliding door 21 is determined to be closed, the drive unit 36 starts to assist the closing operation of the sliding door 21 in S31. Further, when it is determined that the difference Δv does not exceed the predetermined value S4 (i.e., difference Δv falls within a range from S3 to S4), the sliding door 21 is kept retained in the intermediate position in S32 because no force is added to the open direction or the close direction of the sliding door 21. The operation returns to S25 to repeat the same routine.
Accordingly, when the operating force is applied from the outside of the vehicle by a user or the like to any portion of the sliding door 21 for opening or closing the sliding door 21, the automatic open or close operation of the sliding door 21 is started and performed in response to the operating direction of the sliding door 21 based on the detection values vFr and vRr (difference Δv).
According to the aforementioned second embodiment, the following effects may be obtained in addition to those obtained according to the first embodiment.
(1) The strain gauges 51 and 52 are provided at the front bracket 43b and the rear bracket 44b, respectively, that hold the cable 37 (specifically, the other ends 43a and 44a of the wires 43 and 44) connecting the drive unit 36 and the sliding door 21 to each other. Thus, even when the sliding door 21 is stopped in any position between the fully closed position and the fully open position, the opening or closing operation of the sliding door 21 achieved by the application of force to the arbitrary portion of the sliding door 21 for opening or closing the sliding door 21 is detectable at the brackets 43b and 44b. Accordingly, the opening operation or the closing operation of the sliding door 21 is determined, i.e., it is determined which direction the sliding door 21 is operated, on the basis of the detection values of the strain gauges 51 and 52, thereby realizing the opening operation or the closing operation of the sliding door 21 by the drive unit 36. The automatic open or close operation of the sliding door 21 in response to the operating direction by the user can be started.
(2) According to the second embodiment, the strain gauges 51 and 52 are provided at the front bracket 43b and the rear bracket 44b, respectively. Thus, even when the tensile force is generated at only one end portion of the cable 37 depending on the operating direction of the sliding door 21, i.e., even when the strain is generated in only one of the front bracket 43b and the rear bracket 44b, both of the opening operation and the closing operation of the sliding door 21 are detectable.
(3) According to the second embodiment, which direction (open or close) the sliding door 21 is operated is precisely determined on the basis of the stabilized detection values of the strain gauges 51 and 52 obtained after filtered by the thresholds values (after the processes of S13 to S22).
(4) According to the second embodiment, the stabilized detection values of the strain gauges 51 and 52 obtained immediately after filtered by the thresholds values are used as the reference values (KvFr, KvRr). Then, the variations of the detection values of the strain gauges 51 and 52 after the reference values are specified relative to the reference values for the opening operation and the closing operation are calculated to thereby precisely determine which direction (open or close) the sliding door 21 is operated.
(5) According to the second embodiment, the variation of the detection value of the strain gauge 51 after the reference value is specified relative to the reference value (KvFr) for the open direction and the variation of the detection value of the strain gauge 52 after the reference value is specified relative to the reference value (KvRr) for the close direction are calculated, thereby precisely determining the opening operation or the closing operation.
The aforementioned embodiments may be modified or changed as follows. According to the first embodiment, the stabilized detection value of the strain gauge 10 after filtered by the threshold value may be used for determining the opening operation or the closing operation of the rear hatch 1.
According to the first embodiment, as long as the strain is detectable by the strain gauge 10 depending on the operating direction of the sliding door 21 when the sliding door 21 is opened or closed, the strain gauge 10 may be arranged at the other portion connecting the rear hatch 1 and the vehicle body 2 than the bracket 5. For example, the strain gauge 10 may be arranged at an appropriate member that receives a reaction force caused by the opening operation or the closing operation of the rear hatch 1, such as a connecting portion of the bracket 5 with the vehicle body 2, the drive unit 4, the arm member 8, and the rod 9.
According to the second embodiment, as long as the strains are detectable by the strain gauges 51 and 52 in response to the opening operation or the closing operation of the sliding door 21, the strain gauges 51 and 52 may be arranged at the other portion connecting the sliding door 21 and the side body 22 than the brackets 43a and 44a. For example, the strain gauges 51 and 52 may be arranged at an appropriate member that receives a reaction force caused by the opening operation or the closing operation of the sliding door 21, such as a connecting portion between the bracket 36a and the sliding door 21, the drive unit 36 (output drum 40), the pulley mechanism 38 guiding the wires 43 and 44 (guide pulleys 48 and 49), the guide roller unit 26 (base plate 29), the bracket 27.
Instead of the cable 37, a drive belt may be used according to the second embodiment. In addition, instead of the strain gauge, an appropriate load sensor may be used according to the first and second embodiments.
The opening and closing member includes a swing door, a trunk lid, and the like.
According to the aforementioned embodiments, the connecting portion is one of the bracket 5 for attaching the drive unit 4 to the vehicle body 2 or the bracket 36a for attaching the drive unit 36 to the door 21, the brackets 43b and 44b for holding the cable 37 transmitting a drive force, and the pulley mechanism 38.
According to the aforementioned second embodiment, the sensors are constituted by the strain gauges 51 and 52 provided at the front bracket 43b and the rear bracket 44b, respectively, that holds the cable 37 connecting the drive unit 36 with the sliding door 21.
According to the aforementioned second embodiment, the ECU 56 filters the detection values of the strain gauges 51 and 52 by the threshold values S1 and S2 and determines the opening operation or the closing operation of the sliding door 21 based on the filtered detection values.
According to the aforementioned second embodiment, the ECU 56 specifies the reference values KvFr and KvRr based on the detection values of the strain gauges 51 and 52 immediately after filtered by the threshold values S1 and S2, calculates variations of the detection values after the reference values KvFr and KvRr are specified relative to the reference values KvFr and KvRr for the opening operation and the closing operation of the sliding door 21 to determine the opening operation or the closing operation of the sliding door 21, and controls the drive unit 36 to drive the sliding door 21 to open or close the opening portion 22a.
According to the aforementioned second embodiment, a difference between the variations of the detection value of the strain gauge 51 detecting the opening operation after the reference value KvFr is specified relative to the reference value for KvFr the opening operation and the variations of the detection value of the strain gauge 52 detecting the closing operation after the reference value KvRr is specified relative to the reference value KvRr for the closing operation is calculated to determine the opening operation or the closing operation of the sliding door 21, and the drive unit 56 drives the sliding door 21 to open or close the opening portion 22a.
Because the two strain gauges 51 and 52 are provided, both of the opening operation and the closing operation of the sliding door 21 are detectable. Then, the opening operation or the closing operation of the sliding door 21, i.e., which direction the sliding door 21 is operated, is more precisely determined by the calculation of the difference between variations of the detection value of the strain gauge 51 detecting the opening operation after the reference value KvFr is specified relative to the reference value KvFr for the opening operation and variations of the detection value of the strain gauge 52 detecting the closing operation after the reference value KvRr is specified relative to the reference value KvRr for the closing operation.
According to the aforementioned embodiments, regardless of a stop position of the door 1 or 21, i.e., wherever the door 1 or 21 is stopped, the opening operation or the closing operation thereof by the application of force to the arbitrary portion of the opening and closing member is detectable. The auto open or close operation of the door 1 or 21 can be started in response to the operating direction of the door 1 or 21.
The principles, preferred embodiment and mode of operation of the present invention have been described in the foregoing specification. However, the invention which is intended to be protected is not to be construed as limited to the particular embodiments disclosed. Further, the embodiments described herein are to be regarded as illustrative rather than restrictive. Variations and changes may be made by others, and equivalents employed, without departing from the spirit of the present invention. Accordingly, it is expressly intended that all such variations, changes and equivalents which fall within the spirit and scope of the present invention as defined in the claims, be embraced thereby.
Number | Date | Country | Kind |
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2007-282211 | Oct 2007 | JP | national |