JP2019178502A - Movable body moving device - Google Patents

Abstract

To make it possible to control the movement of a moving body, with a simple device configuration, by determining that an obstacle is sandwiched between the edge of the moving body and a base body.SOLUTION: A moving body having a first edge portion and a second edge portion is moved by driving of a first driving unit and a second driving unit between a close position where the first edge portion and the second edge portion are close to a base body and a spaced position where the first edge portion and the second edge portion are apart from the base body. A control unit for controlling the driving of the first driving unit and the second driving unit stops the driving of the first driving unit and the second driving unit when the change value of first driving information and second driving information received from a first sensor and a second sensor caused by the inhibition of the driving of the first driving unit and the second driving unit due to the suppression of the movement of the moving body exceeds a predetermined threshold value. The threshold value is set smaller when there is an abnormal difference between the first drive information and the second drive information than when the first drive information and the second drive information are equal.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a moving body moving apparatus.

  When a moving body such as a back door comes into contact with an obstacle or a human body while moving by a drive unit, the movement of the moving body is inhibited. At this time, the driving force of the driving unit is applied to the obstacle or the human body that inhibits the movement of the moving body via the moving body.

  In particular, when a moving body moves relative to a base body such as a vehicle body, an obstacle or a human body is sandwiched between the base body and the moving body. In order to prevent such an obstacle from being sandwiched between the moving body and the base, there is an automatic opening / closing device that detects contact with an obstacle such as a back door and avoids this.

  As such an automatic opening / closing device, for example, as a determination function for detecting an abnormality, when the current supplied to the electric motor that drives the opening / closing member is detected by the absolute current detection means and is equal to or higher than the reference current, There is an apparatus having a function of determining that an abnormality has occurred (see Patent Document 1).

Japanese Patent Laid-Open No. 7-82594

  However, when the moving body moves, the load of driving force applied to the obstacle is different between the case where the entire moving body comes into contact with the tree branch and the case where the edge of the moving body comes into contact with the human body. If the reference value for determining that the obstacle is sandwiched between the moving body and the base body is uniform, it is difficult to prevent malfunction or abnormality.

  Further, when a sensor that detects a contact portion with an obstacle such as infrared rays is newly provided, the configuration of the apparatus becomes complicated.

  It is an object of the present invention to provide a moving body moving apparatus capable of determining that an obstacle is sandwiched between the edge of a moving body and a base with a simple apparatus configuration and controlling the movement of the moving body. To do.

The moving body moving device of the present invention is
A substrate;
A moving body having a first edge and a second edge;
A first drive unit connected to the first edge side of the movable body;
A second drive unit connected to the second edge side of the movable body;
A control unit that controls driving of the first driving unit and the second driving unit;
A first sensor for detecting a driving state of the first driving unit;
A moving body moving device comprising: a second sensor that detects a driving state of the second driving unit;
The moving body is between a proximity position where the first edge and the second edge are close to the base, and a separation position where the first edge and the second edge are apart from the base. Moved by driving the first drive unit and the second drive unit,
The control unit includes the first drive unit and the second drive unit that are configured to suppress movement of the moving body between first drive information and second drive information received from the first sensor and the second sensor. When the change value caused by the inhibition of driving exceeds a predetermined threshold, the driving of the first driving unit and the second driving unit is stopped,
The threshold is set smaller when there is an abnormal difference between the first drive information and the second drive information than when the first drive information and the second drive information are equivalent. Yes.

  According to the present invention, it is possible to determine that an obstacle has been sandwiched between the edge of the moving body and the base body with a simple apparatus configuration, and to control the movement of the moving body.

It is a schematic side view of the motor vehicle provided with the moving body moving apparatus of embodiment of this invention. 1 is a partially enlarged perspective view of a rear part of an automobile showing a moving body moving apparatus according to an embodiment of the present invention. It is a fragmentary sectional view which shows the principal part structure of an example of the moving body drive part of the moving body moving apparatus of this Embodiment. It is the sectional view on the AA line shown in FIG. 3 which is a fragmentary sectional view which shows the principal part structure of an example of the moving body drive part of the moving body moving apparatus of this Embodiment. It is a block diagram with which it uses for description of the control system of a mobile body moving apparatus. It is a flowchart with which it uses for description of the 1st example of movement control of the moving body in a mobile body moving apparatus. It is a figure where it uses for description of movement control of the moving body in a mobile body moving apparatus. It is a flowchart with which it uses for description of the 2nd example of the movement control of the moving body in a mobile body moving apparatus.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the present embodiment, the moving body moving device is exemplified as a device that is applied to an automobile and controls opening and closing of the back door of the automobile, but the moving body moving device is installed in a structure such as a store or a garage. The present invention can also be applied as a device that controls opening / closing of a shutter, sliding door, hinged door, or folding fold disposed above the opening in front of the structure.

[Overall configuration of moving body moving device]
FIG. 1 is a schematic side view of an automobile provided with a moving body moving apparatus according to the present embodiment. FIG. 2 is a partially enlarged perspective view of the rear part of the automobile showing the moving body moving apparatus according to the embodiment of the present invention.

  As shown in FIGS. 1, 2, and 5, the moving body moving apparatus 1 includes a base body 10, a moving body 20, a first driving unit 30-1, a second driving unit 30-2, and a control unit 50. And a first sensor 61 (see FIG. 5) and a second sensor 62 (see FIG. 5).

  The moving body moving device 1 is a device that moves the moving body 20 with respect to the base body 10, and is in a driving state of the first driving unit 30-1 and a driving state of the second driving unit 30-2 that move the moving body 20. Based on this, the movement of the moving body 20 is controlled. In particular, the moving body moving apparatus 1 includes the driving state of the first driving unit 30-1 and the second driving unit 30-, which are caused by the movement of the moving body 20 caused by contact of an obstacle with the moving body 20 being suppressed. The movement of the moving body 20 is stopped by the change in the driving state 2.

[Substrate 10]
In the moving body moving apparatus 1, the positional relationship between the base body 10 and the moving body 20 changes as the moving body 20 moves. In the present embodiment, the base body 10 is a car body of an automobile and has an opening edge portion 12 that forms an opening.

  In the automobile using the moving body moving apparatus 1 of the present embodiment, the opening edge 12 is provided at the rear part with respect to the traveling direction of the vehicle body.

  The opening edge 12 forms an opening. The opening edge portion 12 may have any shape such as a rectangular shape or a circular shape, but in the present embodiment, the opening edge portion 12 has a shape corresponding to the outer edge of the moving body 20. When the opening edge portion 12 has a shape corresponding to the outer edge of the moving body 20, the opening is closed by the moving body 20. The opening edge portion 12 and the moving body 20 may form a gap to the extent that pinching occurs between the opening edge portion 12 and the moving body 20 when the opening is closed.

[Moving object]
The moving body 20 moves relative to the base body 10 in the moving body moving apparatus 1. The moving body 20 moves by driving the first driving unit 30-1 and the second driving unit 30-2. Details of the first drive unit 30-1 and the second drive unit 30-2 will be described later.

  The moving body 20 includes a first edge 21 and a second edge 22 that are displaced with respect to the base body 10.

  The moving body 20 moves between the proximity position and the separation position with respect to the base body 10. The proximity position is a position where the first edge 21 and the second edge 22 of the moving body 20 are close to the base body 10. In addition, the separation position is a position where the first edge portion 21 and the second edge portion 22 are separated from the base body 10.

  In the present embodiment, the moving body 20 moves between a closed position and an open position with respect to the opening 12 a formed by the opening edge 12 of the base body 10. When the moving body 20 is in the closed position, the moving body 20 closes the opening 12 a of the opening edge 12 of the base body 10. When the moving body 20 is in the closed position, the first edge portion 21 and the second edge portion 22 are located in close proximity to the base body 10. Further, when the moving body 20 is in the open position, the moving body 20 opens the opening 12a of the opening edge 12. When the moving body 20 is in the open position, the first edge portion 21 and the second edge portion 22 are located at a separated position that is separated from the base body 10.

  Note that the open state in the present embodiment is a state in which an object such as a luggage can be entered and exited from the outside through the opening 12a of the opening edge 12 at the rear part of the vehicle. The open state is a state in which the moving body 20 is in a position that allows an object such as a luggage to move to the opposite side through the opening 12a. The movable body 20 in the open state is located at the open position, and the first edge 21 and the second edge 22 are separated from the opening edge 12.

  Further, the closed state is a state in which the opening 12a is closed, and the moving body 20 is in a position in which an object such as a luggage is prevented from moving to the opposite side through the opening 12a.

  The outer peripheral edge of the moving body 20 is provided with a sealing material or the like that is interposed between the opening edge 12 when the opening of the opening edge 12 is closed and ensures shock absorption and water tightness.

  Thereby, when the moving body 20 is located at the closed position, the first edge portion 21 and the second edge portion 22 are located away from the opening edge portion 12 by the thickness of the sealing material. Even if it is the state which obstruct | occluded the opening 12a, it arrange | positions in the position close | similar to the opening edge part 12. FIG.

  In the present embodiment, the upper side portion of the moving body 20 is rotatably attached to the upper edge portion side of the opening edge portion 12 via a shaft portion as a hinge. The moving body 20 turns so that the lower side moves up and down around the shaft, and contacts or moves away from the opening edge 12, thereby opening or closing the opening 12a.

  With this configuration, when the moving body 20 moves from the open position in which the opening 12a is in the open state to the closed position in which the opening 12a is in the closed state, the moving body 20 The two edge portions 22 and the first edge portion 21 and the edge portions corresponding to the second edge portion 22 of the opening edge portion 12 are configured to move relative to each other so as to reduce the angle. Thereby, when the moving body 20 moves from the open position to the closed position, an obstacle is caught between the first edge 21 and the second edge 22 and the opening edge 12 of the base body 10. The obstacle acts on the obstacle.

  In the present embodiment, the position change of the moving body 20 is realized by the turning mechanism described above. However, the mechanism for changing the position of the moving body 20 is not limited to turning, and the slide mechanism and the opening 12a are opened. Alternatively, any mechanism may be used as long as it can be closed.

  Moreover, the 1st edge part 21 and the 2nd edge part 22 are corresponded to each of the right-and-left side part of the mobile body 20 in this Embodiment.

[First driving unit 30-1 and second driving unit 30-2]
The first drive unit 30-1 and the second drive unit 30-2 move the moving body 20 in the opening direction and the closing direction with respect to the opening 12 a of the opening edge portion 12.

  The first drive unit 20-1 is connected to the first edge 21 side of the moving body 20, and the second drive unit 30-2 is connected to the second edge 22 side of the moving body 20. In the present embodiment, the first edge 21 corresponds to the left end of the back door that is the moving body 20, and the second edge 22 corresponds to the right end of the back door that is the moving body 20. To do.

  The 1st drive part 30-1 and the 2nd drive part 30-2 are each provided in the left-right both ends of the moving body 20, and the both edges of the right and left of the opening 12a. If at least one first drive unit 30-1 and two second drive units 30-2 are provided between the left and right ends of the moving body 20 and the left and right edges of the opening 12a, two or more are provided. May be. By moving the moving body 20 by driving each of the drive units 30-1 and 30-2, the moving body 20 is moved relative to the opening edge portion 12, and the opening 12 a is opened or closed. To do.

  The first driving unit 30-1 and the second driving unit 30-2 move the moving body 20 in a direction (opening direction) that opens the opening 12a and a direction (closing direction) that closes the opening 12a. If possible, each of the first drive unit 30-1 and the second drive unit 30-2 may drive the moving body 20 in the same direction and with the same drive amount. Further, as long as each of the first drive unit 30-1 and the second drive unit 30-2 can move the moving body 20 in the opening direction and the closing direction, different driving amounts even in driving in different directions. The mobile body 20 may be driven by the above. In the present embodiment, each moving body drive unit 30 is provided so as to perform the same drive synchronously.

  The first drive unit 30-1 and the second drive unit 30-2 are provided to the opening edge 12 and the moving body 20, and the moving body 20 is provided so as to be relatively movable with respect to the opening edge 12. . Since the moving body 20 pivots with respect to the opening edge portion 12, each of the moving body drive units 30 is driven while turning with respect to the opening edge portion 12 that is a vehicle body so that the moving body 20 can be moved. Attached to the opening edge 12. In the present embodiment, the drive unit 30 configured similarly is used for each of the first drive unit 30-1 and the second drive unit 30-2.

  The drive unit 30 has a rod-like appearance that expands and contracts, and is driven to expand and contract as the two parts move relative to each other. The drive unit 30 includes a drive main body unit and an advance / retreat unit. The drive main body is disposed on one end side of the drive unit 30 and connected to the opening edge 12 side. The advancing / retreating part is disposed on the other end side of the driving part 30 and connected to the moving body 20 side. The advancing / retreating part is attached so as to be able to protrude and retract from the other end side of the drive main body part.

  The drive unit 30 advances and retracts the advance / retreat unit with respect to the drive main body unit in the longitudinal direction of the drive unit 30, so that the moving body 20 is in the fully closed position, that is, the position where the opening 12 a is completely closed, That is, the opening 12a can be moved to a position where the opening 12a is maximized. Each drive unit 30 moves the moving body 20 in the opening direction or the closing direction by converting the rotational movement of the motor or the like into a linear expansion / contraction movement.

  Thus, in the present embodiment, a total of two drive units 30 are provided, one at each of the left and right ends of the rear part of the automobile. As long as the drive unit 30 can open and close the moving body 20, the structure, shape, and arrangement position are not particularly limited.

  FIG. 3 is a partial cross-sectional view illustrating a configuration of a main part of an example of a moving body driving unit of the moving body moving apparatus according to the present embodiment, and FIG. 4 is a cross-sectional view taken along line AA illustrated in FIG.

  In the present embodiment, the moving body drive unit 30 includes a main body cylinder part 31, a slide cylinder part 32, a moving motor 33, a spindle 34, a spindle nut 35, an urging member 36, and the like. In the moving body drive unit 30, the main body cylinder part 31, the moving motor 33, the spindle 34, the urging member 36 and the like correspond to the drive main body part, and the slide cylinder part 32 and the spindle nut 35 correspond to the advance / retreat part.

  One end of the main body cylinder 31 is fixed to the connector 122 so as to be pivotable, and the other end is open. Inside the main body cylinder portion 31, a slide cylinder portion 32 is arranged so as to be slidable in the longitudinal direction so as to protrude from the other end side of the main body cylinder portion 31.

  A fixed end portion 39 that closes the opening on one end side is provided on one end side of the main body cylindrical portion 31. The fixed end 39 has a ball socket part. By connecting the ball of the connector 122 fixed to the opening edge portion 12 to the ball socket portion, the main body cylinder portion 31 is rotatably connected to the opening edge portion 12.

  The moving motor 33 is driven to move the advancing / retreating portion in the longitudinal direction with respect to the driving main body portion to extend and contract the moving body driving portion 30. The moving motor 33 is a direct current motor or an alternating current motor. When the moving body moving apparatus 1 is applied to an automobile, it is desirable to apply a DC motor as the moving motor 33 in consideration of using a DC power supply of the automobile. The moving motor 33 is connected to the control unit 50, and the rotation driving of both the forward rotation and the reverse rotation is controlled by the control unit 50.

  A proximal end portion 34 a of a spindle 34 that extends in the longitudinal direction and is disposed inside the slide cylinder portion 32 is connected to the moving motor 33.

  The spindle 34 is a so-called shaft member, is arranged coaxially with the rotation shaft of the movement motor 33, and is connected to the rotation shaft of the movement motor 33 at the base end portion 34 a. The spindle 34 is disposed on the main body cylinder portion 31 on the base end portion 34a side so as to be rotatable about an axis via a bearing.

  A male threaded portion 341 having a spiral groove shape is formed on the outer periphery of the spindle 34 and is screwed into a spindle nut 35 that is a nut member.

  The spindle nut 35 is driven by the rotation of the spindle 34 and moves on the spindle 34 in the direction of the rotation axis of the spindle 34. That is, the spindle nut 35 can advance and retract in the direction of the rotation axis (length direction) by the rotation of the spindle 34.

  Specifically, the spindle nut 35 is a cylindrical body, and a female screw portion 35 a that is screwed with a male screw portion 341 on the outer periphery of the spindle 34 is provided on the inner peripheral surface on the base end side.

  The tip of the spindle 34 is disposed in the spindle nut 35 and a bearing 41 is attached. The tip of the spindle 34 is movable in the longitudinal direction within the spindle nut 35 via the bearing 41.

  The other end portion of the spindle nut 35 is fixed to the slide end portion 40 via the lid portion 37 together with the other end portion of the slide cylinder portion 32.

  The urging member 36 urges the slide end 40 in a direction away from the fixed end 39, so that the drive unit 30 extends in a direction to resist the weight of the moving body 20 supported by the drive unit 30. Generating power.

  When the moving unit 20 is opened by the drive unit 30, that is, when the slide cylinder unit 32 is moved in the extending direction, a load due to the weight of the moving unit 20 applied when the moving motor 33 rotates the spindle nut 35 is applied. This can be reduced by the force in the extending direction generated by the urging member 36.

  Here, the urging member 36 is a coil spring, and is disposed inside the slide cylinder portion 32 and around the spindle nut 35. The urging member 36 is interposed between the coil base 38 and the slide end portion 40.

  The coil base 38 is fixed in the main body cylindrical portion 31 by the urging force of the urging member 36, but may be fixed by an adhesive, welding, or the like.

  The slide cylinder part 32 is configured to protrude from the other end part of the main body cylinder part 31 and to expand and contract as the entire moving body drive part 30 by sliding and moving in the longitudinal direction. The slide cylinder part 32 has a convex part 32a on the outer periphery. A guide tube portion 43 is disposed between the slide tube portion 32 and the main body tube portion 31 surrounding the slide tube portion 32.

  The guide cylinder portion 43 is disposed inside the main body cylinder portion 31, is restricted from rotating around the axis by the coil base 38, and has a groove-shaped guide portion 43 a extending in the longitudinal direction. A convex part 32a of the slide cylinder part 32 is arranged in the guide part 43a. The slide cylinder portion 32 is movable in the longitudinal direction, but is restricted from rotating in the circumferential direction. Therefore, the guide tube portion 43 functions as a rotation restricting portion that restricts rotation around the axis of the spindle nut 35 fixed to the slide end portion 40 together with the other end portion of the slide tube portion 32.

  When the moving motor 33 is driven in the moving body drive unit 30 configured as described above, the spindle 34 rotates, and the spindle nut that is restricted to move only in the longitudinal direction via the slide cylinder portion 32 by this rotation. 35 moves in the longitudinal direction. As the spindle nut 35 moves, the advance / retreat portion moves, and the slide end portion 40 moves. Since the moving body 20 is connected to the slide end portion 40, the moving body 20 itself can move in the opening direction or the closing direction, and can be positioned in the fully open position or the fully closed position.

  The drive unit 30 includes a configuration in which a spindle nut 35 is screwed onto the spindle 34. This configuration has a self-restraining function in which the spindle 34 restrains the movement of the spindle nut 35 by friction with the spindle nut 35 even when a force for contracting the spindle nut 35 acts on the spindle nut 35 from the moving body 20. You can also have it. When the movement of the spindle nut 35 is restrained by the self-restraining force of the spindle 34 and the spindle nut 35, the movement of the moving body 20 in the closing direction is suppressed.

  The self-restraining function included in the drive unit 30 may be realized by a configuration including a worm wheel and a worm gear, or may be realized by other configurations.

[Control system configuration]
FIG. 5 is a block diagram showing a control system of the moving body moving apparatus 1.

  In the moving body moving apparatus 1, the control system includes a control unit 50, a first sensor 61, and a second sensor 62. The control system of the moving body moving apparatus 1 controls the moving body 20 that is driven by the first driving unit 30-1 and the second driving unit 30-2 each having the moving motor 33 (33-1, 33-2). To do.

  In particular, the control system of the moving body moving apparatus 1 controls the movement of the moving body 20 based on information from the first sensor 61 and the second sensor 62 according to the state when the movement is suppressed.

[First sensor and second sensor]
The first sensor 61 detects the driving state of the first driving unit 30-1, and the second sensor 62 detects the driving state of the second driving unit 30-2.

  The 1st sensor 61 detects the drive state of the 1st drive part 30-1, and outputs the drive state to the control part 50 as 1st drive information. The first sensor 61 can detect the movement of the position of the moving body 20, specifically, the position of the first edge 21 of the moving body 20, depending on the driving state of the first driving unit 30-1.

The second sensor 62 detects the drive state of the second drive unit 30-2 and outputs the drive state to the control unit 50 as second drive information. The second sensor 62 can detect the movement of the position of the moving body 20, specifically, the position of the second edge 22 of the moving body 20 according to the driving state of the second driving section 30-2.
The movement which moves between an open position and a closed position by the 1st sensor 61 and the 2nd sensor 62 detecting the drive state of the 1st drive part 30-1, and the drive state of the 2nd drive part 30-2, respectively. The position of the body 20 can be detected.

  The first drive information and the second drive information are information respectively indicating the drive state of the first drive unit 30-1 and the drive state of the second drive unit 30-2 when the moving body 20 is moved. If the first drive information and the second drive information are information indicating the drive state of the first drive unit 30-1 and the drive state of the second drive unit 30-2, respectively, It may be a signal value for driving each of the one drive unit 30-1 and the second drive unit 30-2.

  The signal value is, for example, that of the moving motor 33 (33-1, 33-2) for making a predetermined driving state corresponding to the driving state of the first driving unit 30-1 and the second driving unit 30-2. The torque value, rotation speed, or supply current value (hereinafter simply referred to as “moving motor 33”) of the first drive unit 30-1 and the second drive unit 30-2 corresponding to the pulse count value indicating the number of rotations per unit time. It is a value corresponding to a physical quantity such as “current value”).

In the present embodiment, the first sensor 61 and the second sensor 62 are configured similarly.
For example, each of the first sensor 61 and the second sensor 62 includes a hall element, and magnetically detects the rotational state of the moving motor 33 (33-1, 33-2), whereby the first driving unit 30- The operation (driving state) of 1 and the 2nd drive part 30-2 and the movement of the position of the mobile body 20 are detected.

  When the sensor includes a Hall element, a plurality of magnets are arranged at intervals in the circumferential direction on a disk provided on the rotation shaft of each moving motor 33 (33-1, 33-2). Hall elements of the first sensor 61 and the second sensor 62 are arranged at positions where any one of the magnets approaches when the disk rotates. The Hall element captures the magnetic force of the magnet that moves with the rotation of the rotation shaft of each moving motor 33 (33-1, 33-2) of the first drive unit 30-1 and the second drive unit 30-2. To generate a pulse. The control unit 50 obtains pulse signals input from the first sensor 61 and the second sensor 62 as drive information (first drive information and second drive information). The control unit 50 determines the drive state (for example, drive speed) of the first drive unit 30-1 and the second drive unit 30-2 and the position of the moving body 20 based on the count value obtained by counting the signals that are the obtained drive information. And calculate. The control unit 50 can calculate the driving speed of the moving body 20 by changing the count value.

  The first sensor 61 and the second sensor 62 generate a pulse signal as drive information, and the control unit 50 counts the pulse signal as movement information of the moving body 20 and calculates the position and driving speed of the moving body 20. Are provided so that the pulse count value can be used.

  Specifically, since the first drive unit 30-1 and the second drive unit 30-2 are respectively connected to the first edge 21 and the second edge 22 of the moving body, the first sensor 61 The movement information of the one edge 21 can be detected, and the second sensor 62 can detect the movement information of the second edge 22. The first sensor 61 and the second sensor 62 not only count the pulse, but also the position of the moving body 20 (the position of the first edge 21 and the second edge 22) and the driving speed based on the count value. After performing the calculation, the calculation result may be output to the control unit 50.

  The first sensor 61 and the second sensor 62 can detect information indicating the operation states of the first drive unit 30-1 and the second drive unit 30-2 in order to obtain information regarding the movement of the moving body 20. Any configuration may be used. Moreover, the 1st sensor 61 and the 2nd sensor 62 move the position of the moving body 20 directly, for example, without detecting each operation | movement of the 1st drive part 30-1 and the 2nd drive part 30-2. It may be detected. The detection method is not limited to magnetic detection using a Hall element, and any method may be used as long as information according to the position of the moving body 20 can be generated. Moreover, although the 1st sensor 61 and the 2nd sensor 62 were demonstrated as a separate sensor here, each drive state of the 1st drive part 30-1 and the 2nd drive part 30-2 is detected in one sensor apparatus. It is good also as a structure which provided the function. Furthermore, although the 1st sensor 61 and the 2nd sensor 62 were demonstrated as what is provided separately from the control part 50 mentioned later here, the 1st sensor 61 and the 2nd sensor 62 were integrated in the control part 50. It may be a thing.

  In addition, when the first sensor 61 and the second sensor 62 output an output value that is not a count value to the control unit 50, for example, a preset count value according to the output results of the first sensor 61 and the second sensor 62 May be acquired from the storage unit or the like. Moreover, although the 1st sensor 61 and the 2nd sensor 62 are comprised separately from the 1st drive part 30-1 and the 2nd drive part 30-2 in this Embodiment, respectively, the 1st drive part 30- 1 and the second drive unit 30-2 may be provided respectively.

[Control unit]
The control unit 50 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The CPU reads a program corresponding to the processing content from the ROM and develops it in the RAM, and performs centralized control of the operation of each block of the moving body moving apparatus 1 in cooperation with the developed program. At this time, various data stored in a storage unit (not shown) are referred to. The storage unit (not shown) is configured by, for example, a nonvolatile semiconductor memory (so-called flash memory) or a hard disk drive. The control unit 50 may be incorporated in, for example, an ECU (Electronic Control Unit) that controls each part of the vehicle, or may be mounted on the moving body drive unit 30. The control unit 50 may be provided separately in a plurality.

  The control unit 50 receives the first drive information output from the first sensor 61 and the second drive information output from the second sensor 62, and uses the first drive information and the second drive information to perform the first drive information. The opening / closing movement of the moving body 20 is controlled via the unit 30-1 and the second driving unit 30-2.

In the normal state, the control unit 50 sets a signal value set in advance corresponding to the position information of the moving body 20 between the open position and the closed position so that the moving body 20 moves at a predetermined target speed. The first drive unit 30-1 and the second drive unit 30-2 are used to move the moving body 20.
The predetermined target speed is a target speed at the time of movement set in advance with respect to the moving body 20, for example, a speed set corresponding to the position of the moving body 20. In the present embodiment, the predetermined target speed corresponds to the initial and final target operations corresponding to the moving state of the moving body 20 from the open position to the closed position or the moving state of the moving body 20 from the closed position to the open position. Each is set, such as setting the speed lower.

  The position information of the moving body 20 is, for example, a value obtained by integrating the counts of pulses output by the first sensor 61 and the second sensor 62 as the first drive information and the second drive information, and a count value that is an accumulated value. Accordingly, the moving speed at each position is set in advance. For example, when the count value at the fully closed position of the mobile body 20 is 0 and the count value at the fully open position of the mobile body 20 is 1200, the value at each position from the fully closed position to the fully open position is the count value 0. In the range of ˜1200, it is set so as to increase from the fully closed position toward the opening direction.

  The control unit 50 controls the driving speed of the moving body 20 based on the current count value that is the current count value of the pulse. For example, when moving the moving body 20 from the fully open position to the fully closed position, the control unit 50 drives the first drive unit 30-1 and the second drive unit 30-2 so as to reach a predetermined target speed. The moving speed of the moving body 20 is controlled.

  Moreover, the control part 50 is based on the change of the 1st drive information which shows the drive state of both the 1st drive part 30-1 and the 2nd drive part 30-2 which move the mobile body 20, and the 2nd drive information. The movement of the moving body 20 can be stopped, assuming that the movement of the moving body 20 has been restrained by the contact of the obstacle.

  The control unit 50 includes the first drive unit 30-1 and the second drive by suppressing the movement of the moving body 20 between the first drive information and the second drive information received from the first sensor 61 and the second sensor 62. The first drive unit 30-1 and the second drive unit 30-2 when a change value caused by the inhibition of driving with the unit 30-2 exceeds a predetermined threshold (see threshold A or threshold B shown in FIG. 7). And stop driving. The stop of driving of the first drive unit 30-1 and the second drive unit 30-2, which is performed when the change value exceeds a predetermined threshold as described above, refers to the first drive unit 30-1. It means that each driving speed with the second driving unit 30-2 becomes zero. That is, the stop of the driving of the first driving unit 30-1 and the second driving unit 30-2 refers to a state in which the moving body 20 stops without applying a load on a moving obstacle such as a human body, In addition to the case where the drive is stationary for a certain period of time, the case where the drive is reversed after opening / closing operation or the case where the drive is reversed is also included.

  The movement of the moving body 20 being suppressed means that an external load is applied to the moving moving body 20 such as an obstacle coming into contact. When an obstacle comes into contact with the moving moving body 20 and an external load is applied to the moving body 20, the driving of the first driving unit 30-1 and the second driving unit 30-2 that move the moving body 20 is inhibited. Occurs.

  Here, based on the first drive information and the second drive information, the control unit 50 determines the position of the moving body 20 and the current speed in order to move the moving body 20 at the target speed, as described above. The first drive unit 30-1 and the second drive unit 30-2 are driven by collating the preset target speed corresponding to the position.

  When inhibition occurs in driving of at least one of the first drive unit 30-1 and the second drive unit 30-2, the control drive value in the one drive unit in which inhibition occurs causes the moving body 20 to be at the target speed. It will rise to move it. That is, when the first drive information and the second drive information are pulse count signals, the pulse count speed of the drive unit on the side where the moving body 20 is inhibited decreases, and the count values are different. In the case where the first drive information and the second drive information are current values, the current value of the drive unit on the side where the moving body 20 is inhibited rises and shows a value different from the other current value. It becomes. At this time, the first drive information and the second drive information are different.

  The predetermined threshold is a value corresponding to the movement of at least one of the first edge 21 and the second edge 22 of the moving body 20 being suppressed. The predetermined threshold is, for example, a first threshold when the first drive information and the second drive information are equivalent, and a second threshold when there is an abnormal difference between the first drive information and the second drive information. Set for each.

The predetermined threshold has an abnormal difference between the first drive information and the second drive information corresponding to the position of the moving body 20, rather than the first threshold when the first drive information and the second drive information are equivalent. In some cases, the second threshold is set smaller.
For example, when the first drive information and the second drive information are count values of pulses per unit time, the first threshold value is an inhibition of driving between the first drive unit 30-1 and the second drive unit 30-2. The second threshold value can be a value corresponding to driving by receiving the resistance value 100N. The first threshold value and the second threshold value may be values that can be collated based on the first drive information and the second drive information, and may be current values or pulse count values.

  The abnormal difference is different from the movement inhibition of the moving body 20 caused by an obstacle acting between the entire moving body 20 or between the first driving unit 30-1 and the second driving unit 30-2. This is a difference between the first drive information and the second drive information, which can be recognized that drive inhibition has mainly occurred with respect to either the first drive unit 30-1 or the second drive unit 30-2. When there is an abnormal difference, it is assumed that the movable body is sandwiched between the edges 21 and 22 of the moving body and the base body 10.

  The first drive information and the second drive information change due to the inhibition of the drive of the first drive unit 30-1 and the second drive unit 30-2 due to the suppression of the movement of the moving body 20. It can be recognized that an action caused by an obstacle such as being caught in the moving body 20 has occurred due to a change in the moving state of the moving body 20. The change in the moving state of the moving body 20 can be grasped by the change in the driving conditions of the first driving unit 30-1 and the second driving unit 30-2 that move the moving body 20. The value indicating the change in the driving status of the first driving unit 30-1 and the second driving unit 30-2 may be changed equally by both the driving units 30-1 and 30-2. Since it may change greatly, it is difficult to uniquely determine the change value, and therefore it can be recognized as the change value of the first drive information and the second drive information. As a change value of the first drive information and the second drive information, if a specific value is shown, for example, the moving body 20 of the total of the first drive information and the second drive information moves at the target speed. The change value with respect to the sum total of the 1st drive information and 2nd drive information which were preset is mentioned. When these change values exceed the above-mentioned predetermined threshold, it can be inferred that an obstacle that suppresses the movement of the moving body has acted.

  In addition, as the change values of the first drive information and the second drive information, the difference between the first drive information and the second drive information is an equivalent case where no difference is recognized and an abnormal difference. Different calculation methods can be adopted. For example, when the difference between the first drive information and the second drive information can be inferred as a difference in a normal situation such as a wind although there is a slight difference, the first drive information and the second drive information are added. If the value is a change in the first drive information and the second drive information, and it can be inferred that a large difference has occurred in only one of the first drive information and the second drive information, The change value can also be regarded as the change value of the first drive information and the second drive information.

  By comparing such a change value with a predetermined threshold value, the control unit 50 comes into contact with an obstacle at one of or between the first edge 21 and the second edge 22 of the moving body 20. And the driving of the first drive unit 30-1 and the second drive unit 30-2 is stopped.

  For example, when there is an abnormal difference between the first drive information and the second drive information, the control unit 50 becomes an obstacle on one side of the first edge 21 and the second edge 22 of the moving body 20. Determine that they are touching. As a result, the abnormal state in which the cutting by the shearing force caused by the sandwiching between the first edge portion 21 or the second edge portion 22 of the moving body 20 and the opening edge portion 12 of the base body 10 occurs can be prevented. It can be distinguished from the contact between the whole and the obstacle.

  In the present embodiment, the control unit 50 determines the position of the back door as the moving body 20 based on the first drive information and the second drive information from the first sensor 61 and the second sensor 62. The position information of the moving body 20 determined by the control unit 50 is stored as needed in a storage unit (not shown). In addition, when there is an operation instruction or the like of the moving body 20, the control unit 50 controls the driving speed of the moving body 20 according to the current position information of the moving body 20.

[Moving control of moving body 20 in moving body moving apparatus 1]
Hereinafter, an example of movement control of the moving body in the moving body moving apparatus 1 will be described.
In the description of the movement control of the moving body 20, the first drive information and the second drive information are the first drive as signal values indicating the drive states of the first drive unit 30-1 and the second drive unit 30-2. The current value for driving the moving motor 33 of the unit 30-1 and the second drive unit 30-2 will be described. For example, the signal value is changed to the first drive unit 30-1 and the second drive unit 30-2. It is good also as a count value of the change of the pulse per unit time of the motors 33-1 and 33-2 required for movement, or a torque value.

[First Example: Stopping Movement of Moving Body 20 Due to Overall Operating State of First Driving Unit 30-1 and Second Driving Unit 30-2]
FIG. 6 is a flowchart for explaining a first example of movement control of the moving body in the moving body moving apparatus 1. Note that the control in FIG. 6 is based on the premise that the control unit 50 receives an operation instruction to close the moving body 20 when the moving body 20 is in the open state. The moving body moving apparatus 1 can be similarly controlled by control when the control unit 50 receives an operation instruction to open the moving body 20.

  As shown in FIG. 6, the control unit 50 drives the first drive unit 30-1 and the second drive unit 30-2 to move the moving body 20 (step S101). At this time, the moving speed of the moving body 20 is controlled to be a preset target speed.

  Next, based on the first drive information and the second drive information from the first sensor 61 and the second sensor 62, the control unit 50, here, as the first drive information and the second drive information, the first drive unit 30. −1 and the total supply current value (referred to as “total current value”) to the second drive unit 30-2 are determined whether or not the threshold value A, which is the second threshold value, is exceeded (step S102). As a result of the determination, if the change in the total current value of the first drive unit 30-1 and the second drive unit 30-2 does not exceed the threshold A (step S102: NO), the control unit 50 It is considered that there is no obstacle that obstructs the movement, and step S102 is repeated.

  On the other hand, as a result of the determination, if the total current value of the first drive unit 30-1 and the second drive unit 30-2 exceeds the threshold A (step S102: YES), the current of the first drive unit 30-1 It is determined whether or not there is a difference between the value and the current value of the second drive unit 30-2 (step S103).

  If there is a difference between the current value of the first drive unit 30-1 and the current value of the second drive unit 30-2 (step S103: YES), the first edge 21 or the second edge 22 and the base 10 Therefore, it is assumed that the obstacle is caught, and the driving of the first driving unit 30-1 and the second driving unit 30-2 is stopped, and the movement of the moving body 20 is stopped (step S104). Thereafter, this control ends.

  If there is no difference between the current value of the first drive unit 30-1 and the current value of the second drive unit 30-2 (step S103: NO), the total of the first drive unit 30-1 and the second drive unit 30-2 It is determined whether or not the current value exceeds a threshold value B that is a first threshold value (step S105). In step 103, when the difference between the current values of the first drive unit 30-1 and the second drive unit 30-2 exceeds a certain value, the first drive unit 30-1 and the second drive unit 30. It can be determined that there is a difference in current value between -2.

  If the total current value does not exceed the threshold B as a result of the determination (step S105: NO), the process returns to step S102 and the subsequent processing is repeated. In step S105, if the total current value exceeds the threshold value B (step S105: YES), the obstacle contacts the moving body 20, specifically, the first edge 21 and the second edge in the moving body 20. It is determined that an obstacle is in contact with the region between 22 and the driving of the first driving unit 30-1 and the second driving unit 30-2 is stopped, and the movement of the moving body 20 is stopped (step S104). . Thereafter, this control ends.

  FIG. 7 is a diagram for explaining the movement control of the moving body in the moving body moving apparatus 1. In FIG. 7, it is assumed that the control unit 50 receives the operation instruction for closing the moving body 20 and moves it to the fully closed position when the moving body 20 is located at the fully open position. . As shown in FIG. 7, in the fully closed state in which the opening 12 a is closed by the back door which is the moving body 20, the first edge 21 and the second edge 22 sandwich the sealing material of the outer peripheral edge, and the opening edge It is arranged at a position close to the part 12.

As shown in FIG. 7, the threshold A and the threshold B are set according to the position of the moving body 20, in this embodiment, the angle with respect to the opening edge 12 of the back door, and are uniform at all positions or angles. It is not installed.
The threshold A and the threshold B are both set higher than when the door position, which is the position of the moving body 20, is located between the fully open state and the fully closed state when the door is in the fully open state and the fully closed state. Yes. This is because the control drive values of the first drive unit 30-1 and the second drive unit 30-2 are set in order to position the moving body 20 against the weight of the moving body 20 in the open position where the fully opened state, for example, This corresponds to a high current value for driving the driving units 30-1 and 30-2. When the position of the door which is the moving body 20 is close to the fully closed position, for example, the first driving unit 30-1 and the second driving unit so that the door is latched by a latch mechanism (not shown). This corresponds to the signal value 30-2 becoming higher.

  As described above, in the first example, the obstacle that inhibits the movement of the moving body 20 is sandwiched, and the total current value of the first drive unit 30-1 and the second drive unit 30-2 exceeds the threshold A. Whether or not (step 102) and whether or not the threshold value B is exceeded (step 105), but the total current value of the first drive unit 30-1 and the second drive unit 30-2 is changed. The current value of the first drive unit 30-1 or the current value of the second drive unit 30-2 may be determined based on whether each threshold value is exceeded. Also, whether the total current value of the first drive unit 30-1 and the second drive unit 30-2, the current value of the first drive unit 30-1, and the current value of the second drive unit 30-2 exceed the respective threshold values. You may determine whether the obstruction has been caught depending on the result.

[Second Example: Stopping Movement of Moving Body 20 Due to Difference in Driving State between First Driving Unit 30-1 and Second Driving Unit 30-2]
FIG. 8 is a flowchart for explaining the moving body movement control in the moving body moving apparatus 1. Note that the control in FIG. 8 is the control when the control unit 50 receives an operation instruction to close the moving body 20 when the moving body 20 is in the open state, as in FIG. Is assumed. According to the moving body moving apparatus 1, the control can be similarly performed even when the control unit 50 receives an operation instruction to open the moving body 20.

  As shown in FIG. 8, the control unit 50 drives the first driving unit 30-1 and the second driving unit 30-2 to move the moving body 20 (step S201). At this time, the moving speed of the moving body 20 is controlled to be a preset target speed.

  Next, the control part 50 is the 1st drive information and 2nd drive which are each current value of the 1st drive part 30-1 and the 2nd drive part 30-2, and is received from the 1st sensor 61 and the 2nd sensor 62. It is determined whether or not there is a difference in the current value as information (step S202). In step 202, when the difference between the current values of the first drive unit 30-1 and the second drive unit 30-2 exceeds a certain value, the first drive unit 30-1 and the second drive unit 30. It can be determined that there is a difference in current value between -2.

  If there is a difference between the current values of the first drive unit 30-1 and the second drive unit 30-2 as a result of the determination (step S202: YES), the first drive unit 30-1 and the second drive unit 30- It is determined whether or not the total current value of 2 exceeds the threshold A (step S203).

  In step S203, as a result of the determination, if the total current value of the first drive unit 30-1 and the second drive unit 30-2 does not exceed the threshold value A (step S203: NO), the control unit 50 moves the moving body. It is considered that there is no obstacle sandwiched in the movement of 20, and the process returns to step S202, and the subsequent processing is repeated.

  On the other hand, if it is determined in step S203 that the total current value of the first drive unit 30-1 and the second drive unit 30-2 exceeds the threshold A (step S203: YES), the process proceeds to step S205. .

  If there is no difference between the current value as the first drive information and the current value as the second drive information in step S202 (step S202: NO), the current value of the first drive unit 30-1 and the second drive unit 30 are determined. It is determined whether or not the current value of −2 exceeds the threshold value B (step S204).

  As a result of the determination, if it is determined that there is no difference between the current value of the first drive information and the current value of the second drive information and the change in both current values does not exceed the threshold B (step S204: NO), step S202 is performed. Return to and repeat the subsequent processing.

  On the other hand, when the control unit 50 determines that there is no difference between the current value of the first drive information and the current value of the second drive information and the change in both current values exceeds the threshold B (step S204: YES). The obstacle is in contact with the moving body 20, specifically, it is determined that the obstacle is in contact with the part between the first edge 21 and the second edge 22 in the moving body 20, and the first drive unit The drive of 30-1 and the 2nd drive part 30-2 is stopped, and the movement of the mobile body 20 is stopped (step S205). Thereafter, this control ends.

  As described above, in the second example, whether or not the total current value of the first drive unit 30-1 and the second drive unit 30-2 exceeds the threshold A due to the sandwiching of obstacles that inhibit the movement of the moving body 20 Whether or not (step 102) and whether or not the threshold value B has been exceeded (step 105) is determined, as in the first example, the first drive unit 30-1 and the second drive unit 30-2. Instead of the total current value, the current value of the first drive unit 30-1 or the current value of the second drive unit 30-2 may be determined based on whether or not each threshold value is exceeded. Also, whether the total current value of the first drive unit 30-1 and the second drive unit 30-2, the current value of the first drive unit 30-1, and the current value of the second drive unit 30-2 exceed the respective threshold values. You may determine whether the obstruction has been caught depending on the result.

  According to the present embodiment as described above, in the movement of the moving body 20, when the movement of the moving body 20 is suppressed by an obstacle coming into contact with the moving body 20, the first drive unit 30-1 and the first When the drive of the second drive unit 30-2 is hindered and the change values of the first drive information and the second drive information exceed a predetermined threshold, the movement of the moving body 20 is stopped.

  The threshold is set smaller when there is an abnormal difference between the first drive information and the second drive information than when the first drive information and the second drive information are equal. That is, an obstacle comes into contact with one of the first edge 21 and the second edge 22 of the moving body 20 to which the first drive unit 30-1 and the second drive unit 30-2 are connected, that is, sandwiched. If there is, the moving body 20 can be stopped by determining the change values of the first drive information and the second drive information with a small threshold (here, the threshold A). Therefore, it is determined that an obstacle is sandwiched between the edge of the moving body 20 (one of the first edge 21 and the second edge 22) and the base body 10 with a simple apparatus configuration, and the movement You can control the movement of your body.

In the present embodiment, the moving body 20 is a back door that closes the opening 12 a of the opening edge 12 in the base 10, and the angle formed by the first edge 21 and the second edge 22 and the opening edge 12 is small. It moves relative to the base 10 so as to be.
The threshold B assumes a case where an obstacle collides with the lower side between the left and right sides (the first edge 21 and the second edge 22) in the moving body 20, and the threshold A is the left and right of the moving body 20. Are set on the assumption that sandwiching between one of the two side portions (the first edge portion 21 and the second edge portion 22) and the opening edge portion 12 is performed.
In the sandwiching between one of the left and right sides (the first edge 21 and the second edge 22) of the moving body 20 and the opening edge 12, a shearing action acts on the obstacle, and the moving body 20 It is conceivable that the obstacle is damaged more than the case where the obstacle comes into contact with the lower side of the obstacle.

  In the present embodiment, the first drive information and the second drive information are inhibited from being driven by the first drive unit 30-1 and the second drive unit 30-2 by suppressing the movement of the moving body 20. Compared with the change value to be generated, the threshold value for stopping the moving body 20 is compared with the case where the first drive information and the second drive information are equivalent (threshold value B), that is, the case where the lower side portion of the moving body 20 makes contact. In the case where there is an abnormal difference between the first drive information and the second drive information (threshold A), it is set smaller. Therefore, apart from detecting a large collision with the lower side of the moving body 20, one of the left and right sides (the first edge 21 and the second edge 22) of the moving body 20 and the opening edge 12. It is possible to sensitively detect an obstacle sandwiched between the two.

  Note that the control as the first example shown in FIG. 6 compares the change in the total current value with the threshold A as the first drive information and the second drive information in step S102, and if the threshold A is not exceeded, Since the process is repeated, unlike the control as the second example shown in FIG. 8, it is not necessary to make a comparison with the threshold B when there is no obstacle contact with the moving body 20, so that power saving is achieved. be able to.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  The embodiment of the present invention has been described above. The above description is an illustration of a preferred embodiment of the present invention, and the scope of the present invention is not limited to this. That is, the description of the configuration of the apparatus and the shape of each part is an example, and it is obvious that various modifications and additions to these examples are possible within the scope of the present invention.

  The moving body moving device according to the present invention has an effect that it is possible to control the movement of the moving body by determining that an obstacle is sandwiched between the edge of the moving body and the base body with a simple device configuration, For example, it is useful as an apparatus applied to opening / closing control of a back door of an automobile.

DESCRIPTION OF SYMBOLS 1 Mobile body moving apparatus 10 Base body 12 Opening edge part 12a Opening 20 Mobile body 21 1st edge part 22 2nd edge part 30 Drive part 30-1 1st drive part 30-2 2nd drive part 31 Main body cylinder part 32 Slide cylinder Part 32a Protruding part 33, 33-1, 33-2 Moving motor 34 Spindle 34a Base end part 35 Spindle nut 35a Female thread part 36 Energizing member 37 Lid part 38 Coil base 39 Fixed end part 40 Slide end part 41 Bearing 43 Tube Part 43a guide part 50 control part 61 first sensor 62 second sensor 122 connector 341 male screw part

Claims (3)

A substrate;
A moving body having a first edge and a second edge;
A first drive unit connected to the first edge side of the movable body;
A second drive unit connected to the second edge side of the movable body;
A control unit that controls driving of the first driving unit and the second driving unit;
A first sensor for detecting a driving state of the first driving unit;
A moving body moving device comprising: a second sensor that detects a driving state of the second driving unit;
The moving body is between a proximity position where the first edge and the second edge are close to the base, and a separation position where the first edge and the second edge are apart from the base. Moved by driving the first drive unit and the second drive unit,
The control unit includes the first drive unit and the second drive unit that are configured to suppress movement of the moving body between first drive information and second drive information received from the first sensor and the second sensor. When the change value caused by the inhibition of driving exceeds a predetermined threshold, the driving of the first driving unit and the second driving unit is stopped,
The threshold is set smaller when there is an abnormal difference between the first drive information and the second drive information than when the first drive information and the second drive information are equivalent. ,
Mobile body moving device. The substrate has an opening edge forming an opening;
The moving body moves between an open position and a closed position;
When the moving body is located at the closed position, the moving body closes the opening, and the first edge and the second edge are close to the opening edge.
The moving body moving apparatus according to claim 1. When the moving body moves from the open position to the closed position,
The moving body moves relative to the base body so that an angle formed by the first edge and the second edge and the opening edge is small.
The moving body moving device according to claim 2.

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