JP2009161038A - Vehicle seat belt device - Google Patents

Abstract

An object of the present invention is to prevent an excessive load from being generated by a belt operation by an occupant.
A seat belt device for a vehicle (1) is configured to wind a belt (5) by transmitting a driving force to the belt reel (14) and a winding spring that urges a belt reel (14) around which the belt (5) is wound. A motor 10 to be performed, a clutch for connecting / disconnecting transmission of driving force between the motor 10 and the belt reel 14 by a rotational difference between the belt reel 14 and the motor 10, and a motor control unit for controlling an energization amount to the motor 10 56, a rotation detection device 24 and a winding position detection unit 51 that detect the position of the belt 5 by detecting the rotation position of the belt reel 14, and an overload determination unit that performs an overload determination based on the current flowing to the motor 10. 53, and when the withdrawal of the belt 5 is detected based on the position of the belt 5 under a current condition where the overload determination by the overload determination unit 53 is not executed. And a clutch control unit 54 for instructing execution.
[Selection] Figure 2

Description

  The present invention relates to a vehicle seat belt device.

Conventionally, for example, when an external force acting against the belt winding is applied during the winding of the belt by the forward rotation of a motor that drives a reel around which the belt is wound and applies tension to the belt to restrain the occupant. A device is known that detects a restraining current flowing through a motor when the output shaft of the motor is locked, reverses the motor, rotates the gear of the clutch in the pulling direction, and stops the motor after releasing the clutch (for example, , See Patent Document 1 and Patent Document 2).
JP 2006-69334 A JP 2006-27587 A

  By the way, in the apparatus according to the above-described prior art, a current that increases when the output shaft of the motor is locked, that is, a binding current, is detected, and the motor is loaded when a remounting operation is performed by the occupant while the belt is being stored. It is designed to prevent becoming. However, there is a possibility that the presence / absence of the remounting operation by the occupant cannot be properly determined simply by detecting the restraining current. In other words, since the current flowing through the motor increases when the motor stops rotating, when the motor changes from forward rotation to reverse rotation instantaneously, for example, when the occupant suddenly pulls out while the belt is being stored, etc. In this case, it is difficult to properly detect an increase in the current flowing through the motor, and the assist operation of the motor with respect to the winding of the belt cannot be stopped appropriately. The problem of becoming.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a vehicle seat belt device capable of preventing an excessive load from being generated due to a belt operation by an occupant.

  In order to solve the above problems and achieve the object, a vehicle seat belt device according to a first aspect of the present invention includes a belt reel (for example, a belt 5 for winding a belt (for example, the belt 5 in the embodiment)). Belt reel 14) in the embodiment, urging means for urging the belt reel in the winding direction (for example, the winding spring 25 in the embodiment), and transmitting the driving force to the belt reel. The motor (for example, the motor 10 in the embodiment) that winds the belt by the rotation of the belt reel and the motor due to the rotational difference between the motor and the belt reel due to the rotation difference between the motor and the belt reel. A vehicle seat belt comprising a clutch mechanism (for example, a clutch in the embodiment) that performs the above-described operation and a control unit (for example, the processing device 46 in the embodiment) that controls the amount of power supplied to the motor. A position sensor that detects the position of the belt by detecting the rotation position of the belt reel (for example, the rotation detection device 24 and the winding position detection unit 51 in the embodiment), and the control The unit includes an overload determination unit (for example, an overload determination unit 53 in the embodiment) that performs an overload determination based on a current flowing to the motor, and a current condition in which the overload determination by the overload determination unit is not performed. Clutch release means (for example, the clutch control unit 54 in the embodiment) for instructing the release of the clutch mechanism when the belt withdrawal is detected based on the detection signal output from the position sensor below. Prepare.

  Further, in the vehicle seat belt device according to the second aspect of the present invention, when the control unit detects the withdrawal of the belt after the release instruction is issued by the clutch release means, the clutch mechanism is connected. Feeding means (for example, a feeding control unit 55 in the embodiment) that feeds the belt while maintaining is provided.

  A vehicle seat belt device according to a third aspect of the present invention includes a belt reel (for example, the belt reel 14 in the embodiment) around which a belt (for example, the belt 5 in the embodiment) is wound, A biasing means for biasing the belt reel in the winding direction (for example, the winding spring 25 in the embodiment) and a motor for winding the belt by transmitting a driving force to the belt reel (for example, The clutch mechanism (for example, in the embodiment) that connects and disconnects the transmission of the driving force between the motor and the belt reel by the rotational difference between the motor 10) in the embodiment and the belt reel and the motor. Clutch) and a control unit (for example, the processing device 46 in the embodiment) for controlling the amount of current supplied to the motor, the vehicle seat belt device comprising: a rotational position of the belt reel; And a position sensor that detects the position of the belt by detecting the position of the belt (for example, the rotation detection device 24 and the winding position detection unit 51 in the embodiment). An overload determination unit that performs load determination (for example, an overload determination unit 53 in the embodiment), and a detection signal that is output from the position sensor under a current condition in which the overload determination by the overload determination unit is not performed. When the belt pull-out is detected on the basis of the above, a feed means (for example, a feed control unit 55 in the embodiment) that feeds the belt while maintaining the connected state of the clutch mechanism is provided.

  According to the vehicle seat belt device of the first aspect of the present invention, the belt is instructed to release the clutch when the position sensor detects the withdrawal of the belt under a current condition where the overload determination is not performed. Even when an increase in the current flowing to the motor is not detected when the occupant is pulled out during storage, the motor is loaded (resistive) against the belt with the clutch being released. Can be prevented.

  Further, according to the vehicle seat belt device of the second aspect of the present invention, when the belt withdrawal is detected after the release instruction by the clutch release means is detected, the motor is assisted by assisting the withdrawal. A passenger's intention can be appropriately reflected in the behavior.

  Further, according to the vehicle seat belt device of the third aspect of the present invention, when the belt sensor is detected by the position sensor under the current condition in which the overload determination is not performed, the drawer is assisted by the motor. Even when the increase in the current flowing through the motor is not detected when the belt is retracted by the occupant during the storage of the belt, the intention of the occupant can be appropriately reflected in the behavior of the motor.

Hereinafter, an embodiment of a vehicle seat belt device of the present invention will be described with reference to the accompanying drawings.
A vehicle seat belt device 1 according to the present embodiment is a so-called three-point seat belt device capable of restraining an occupant 3 seated on a seat 2 as shown in FIG. 1, for example, and is attached to a center pillar (not shown). The belt 5 is pulled out from the retractor 4 in a substantially vertical direction, and the belt 5 is inserted into a through anchor 6 supported on the upper side of the center pillar. It is fixed to the vehicle body floor via the outer anchor 7. A tongue plate 8 is inserted between the through anchor 6 and the outer anchor 7 of the belt 5, and the tongue plate 8 is attached to and detached from the buckle 9 fixed to the vehicle body floor of the seat 2 on the inner side of the vehicle body. It is possible.

In the retractor 4, for example, as shown in FIGS. 2 to 4, the belt reel 14 around which the belt 5 is wound is rotatably supported by the retractor frame 15, and the shaft 14 a of the belt reel 14 is externally connected to the retractor frame 15 ( For example, it protrudes forward).
The belt 5 is wound around the retractor 4 in an initial state (for example, an unmounted state), and is pulled out from the belt reel 14 by the occupant 3 while being guided by the belt guide portion 16, and the tongue plate 8 is mounted on the buckle 9. By fixing, the body of the occupant 3 (for example, a shoulder portion and a waist portion) is restrained with respect to the seat 2.
In this vehicle seat belt device 1, for example, when a collision impact is detected or when a rollover occurs, the winding of the belt 5 causes the driving force of the motor 10 to apply a rotational force to the belt reel 14 and the explosive pretensioner mechanism. It is performed by the thrust of 17 explosives.

The shaft 14a of the belt reel 14 is connected to a rotating shaft 10a of the motor 10 via a power transmission mechanism 18 having a power connection / disconnection clutch and a gear mechanism (not shown).
The power transmission mechanism 18 is provided with an output shaft 19 that is coaxially connected to the shaft 14 a of the belt reel 14, and the output shaft 19 projects forward.
The clutch in the power transmission mechanism 18 is controlled by the processing device 46 described later, and the motor 10, the output shaft 19, and the belt reel according to the rotational state of the motor 10, for example, the rotational difference between the belt reel 14 and the motor 10. 14 can be disconnected.

For example, when the motor 10 rotates in the forward rotation direction (that is, the direction in which the belt reel 14 is rotated forward and the belt 5 is pulled), the clutch connects the motor 10 to the output shaft 19 and the belt reel 14.
On the other hand, when the motor 10 rotates in the reverse direction (that is, the direction in which the belt reel 14 is reversely rotated and the belt 5 is fed), the clutch disconnects the connection between the motor 10 and the output shaft 19 and the belt reel 14. However, even when the motor 10 is in the reverse rotation state, an external force larger than the driving force in the reverse rotation direction of the motor 10 (for example, the rotational driving force accompanying the pulling operation of the belt 5 by the occupant) acts in the reverse rotation direction of the motor 10. In this state, the clutch maintains the connection between the motor 10 and the output shaft 19 and the belt reel 14, and when the external force becomes smaller than the driving force in the reverse direction of the motor 10, the motor 10, the output shaft 19 and the belt. The connection with the reel 14 is cut off.

  The retractor 4 includes an emergency lock mechanism 20 that mechanically locks the delivery of the belt 5 when, for example, a deceleration exceeding a predetermined value acts on the vehicle.

A disc-shaped magnetic rotor 21 having a magnetic ring 21 a on the outer periphery is connected to the front end portion of the output shaft 19, and a connecting shaft 22 fixed to the axial center position of the magnetic rotor 21 protrudes forward. Yes. The magnetic ring 21a is magnetized so that different magnetic poles appear alternately along the circumferential direction, and the magnetism differs depending on the position in the circumferential direction.
A pair of Hall elements 23A and 23B spaced apart in the circumferential direction are arranged in close contact with each other on the outer peripheral side of the magnetic rotor 21, and the magnetic rotor 21 and the Hall elements 23A and 23B are rotated by the belt reel 14. A rotation detecting device 24 for detecting the state is configured.

Further, a winding spring 25 for rotating and energizing the belt reel 14 in the winding direction of the belt 5 is coupled to the connecting shaft 22 integral with the magnetic rotor 21. The winding spring 25 is, for example, a mainspring spring, and an inner peripheral end of the winding spring 25 is coupled to the connecting shaft 22 and an outer peripheral end is coupled to an inner wall of the front cover 26 of the retractor 4.
The front cover 26 is integrally coupled to the retractor frame 15. A shaft hole 27 is formed at the tip of the connecting shaft 22, and a guide protrusion 28 protruding from the front cover 26 is inserted into the shaft hole 27.
In the state where the belt reel 14 and the motor 10 are separated by the clutch disengaging operation, the tension by the winding spring 25 acts on the belt 5.
When the belt reel 14 is rotated in the winding direction of the belt 5 by the elastic force of the winding spring 25 when the motor 10 is stopped in a state where the belt reel 14 and the motor 10 are connected by the clutch, the clutch Thus, the connection between the motor 10 and the belt reel 14 is released.

  The front cover 26 has a bottomed cylindrical spring accommodating portion 26a in which the take-up spring 25 is accommodated, a large diameter formed coaxially with the spring accommodating portion 26a and larger in diameter than the spring accommodating portion 26a. A cylindrical portion 26b and a substantially rectangular sensor housing portion 26c connected to the lower end of the large-diameter cylindrical portion 26b are provided. The large-diameter cylindrical portion 26b accommodates the magnetic rotor 21 of the rotation detecting device 24, and the sensor accommodating portion 26c accommodates a substrate (not shown) on which the Hall elements 23A and 23B are mounted.

A substantially disc-shaped partition wall 30 having a through hole 30a through which the connecting shaft 22 is inserted is disposed between the spring accommodating portion 26a and the large-diameter cylindrical portion 26b of the front cover 26, and the interior of the front cover 26 is The partition wall 30 is divided into a spring housing space 31 on the bottom side and a rotor housing space 32 on the opening side.
A pair of support protrusions 30b and 30b are provided on the outer peripheral edge of the partition wall 30, and these support protrusions 30b and 30b are fitted into positioning grooves (not shown) on the peripheral wall of the large-diameter cylindrical part 26b. ing. The positioning groove is formed up to a position reaching the boundary position between the spring accommodating portion 26a and the large-diameter cylindrical portion 26b, and the partition wall 30 is moved to the front cover 26 by bringing the support protrusions 30b and 30b into contact with the end portions of the positioning groove. It is designed to be positioned inside.

  The front cover 26 has a sub cover 33 that is slightly smaller than the front cover 26 after the winding spring 25, the partition wall 30, and the magnetic rotor 21 are accommodated inside the front cover 26. It is mated. The spring accommodating space 31 is filled with a lubricant for lubricating the take-up spring 25. The sub cover 33 is fixed to the front cover 26 with screws or the like. The bottom wall 33 a of the sub cover 33 is provided with an opening 40 for connecting the output shaft 19 of the power transmission mechanism 18 to the magnetic rotor 21.

The sub-cover 33 is provided with a substantially cylindrical arc wall 33b fitted to the large-diameter cylindrical portion 26b of the front cover 26, and is connected to both ends of the arc wall 33b and is connected to the sensor housing portion 26c of the front cover 26. And a rectangular wall 33c to be fitted, and inside the rectangular wall 33c, a sensor installation space 34 for securing a substrate on which the Hall elements 23A and 23B are mounted is secured.
The substrate is held in a holding case 35. The holding case 35 is disposed in a sensor installation space 34 in the sub cover 33 and is locked by locking claws 36 and 36 protruding from the sub cover 33. .

  The holding case 35 is open on the side facing the bottom of the front cover 26, and the arcuate wall 35 a facing the outer peripheral edge of the magnetic rotor 21 in combination with the arcuate wall 33 b of the sub-cover 33 when assembled to the front cover 26. A circular wall is formed. The front end surfaces of the arc walls 33b and 35a come into contact with the outer peripheral edge of the partition wall 30 from the rotor accommodating space 32 side in a state where the sub cover 33 is fitted and fixed to the front cover 26. .

  The winder spring 25, the partition wall 30, the magnetic rotor 21 and the like are accommodated in the front cover 26, and the sub cover 33 and the holding case 35 attached to the opening side of the front cover 26 constitute a cover unit 42. The power transmission mechanism 18 and the retractor frame 15 are integrated by bolt fastening or the like.

The pair of Hall elements 23A and 23B of the rotation detecting device 24 are connected to the processing device 46 via a signal processing sensor circuit 45, and a pulse signal corresponding to a magnetic change detected by each Hall element 13A and 13B is a sensor. A predetermined process is performed in the circuit 45 and then input to the processing device 46.
The A-phase and B-phase pulse signals output from the hall elements 23A and 23B to the processing device 46 are used as feedback signals for driving the motor 10 in the processing device 46. For example, the processing device 46 detects the rotation amount of the belt reel 14 (that is, the amount of the belt 5 withdrawn) by counting the pulse signals of each phase of A phase and B phase. The rotation direction of the belt reel 14 is detected by comparing the rise of the waveform of the pulse signal.

For example, “0” is associated with the Hi value of each pulse signal of the A phase and the B phase output from each Hall element 23A, 23B, “1” is associated with the Low value, and the corresponding values of the A phase and the B phase are Obtained by converting the decimal value by adding the corresponding values of the A phase and the B phase when assuming that the corresponding value of the A phase is a numerical value one digit higher than the corresponding value of the B phase. The value (hereinafter simply referred to as “added value of phase A and phase B”) changes as shown in FIG.
For example, assuming that the pulse waveforms of the A phase and the B phase shown in FIG. 6 are those when the belt reel 14 rotates forward, the added value of the A phase and the B phase has a predetermined first change (3 → 2). When the belt reel 14 rotates in the reverse direction, the added value of the A phase and the B phase indicates a predetermined second change (3 → 1 → 0 → 2...). Therefore, when a change other than the predetermined first change and second change is detected, it can be determined that the state is abnormal.

Further, when the added value of the A phase and the B phase indicates a predetermined first change (3 → 2 → 0 → 1...), One change of the added value of the A phase and the B phase (previous value− When the count value of “current value” is “+1” and the added value of the A phase and the B phase indicates a predetermined second change (3 → 1 → 0 → 2...), The A phase and the B phase If the count value of one change (previous value−current value) of the addition value of “−1” is “−1”, the count value of the change in the addition value between the A phase and the B phase is counted while the belt reel 14 rotates. The total count value (cnt) of the pulse corresponding to the winding amount of the belt 5 obtained by this changes as shown in Table 1 below, for example.
Then, the correspondence between the change in the added value of the A phase and the B phase (previous value−current value) and the count value changes as shown in Table 2 below, for example. In Table 2 below, “+1” indicates normal rotation of the belt reel 14, “−1” indicates reverse rotation of the belt reel 14, and “0” indicates no change in the added value between the A phase and the B phase. "X" indicates an abnormal state that cannot be forward rotation or reverse rotation.

  In this vehicle seat belt device 1, the motor 10 is stopped when the occupant wears the belt 5 or during normal running, and the motor 10 is driven when the unattached state of the belt 5 is detected by releasing the buckle 9 or the like. The belt 5 is started and wound up to a predetermined storage position. At this time, the winding amount (or the drawing amount) of the belt 5 and the moving direction are detected by the rotation detection device 24, and the motor 10 is driven and controlled based on the detection result of the rotation detection device 24.

The processing device 46 includes, for example, a winding position detection unit 51, a drawer detection unit 52, an overload determination unit 53, a clutch control unit 54, a feed control unit 55, and a motor control unit 56. ing.
The processing device 46 includes, for example, a detection signal output from a buckle switch (buckle SW) 61 that detects whether or not the tongue plate 8 is fixed to the buckle 9, and a radar that detects an object existing in the outside of the vehicle. A detection signal output from an external sensor 62 composed of a camera and a camera, a detection signal output from an acceleration sensor 63 that detects acceleration and deceleration of the vehicle body, and a detection signal output from a yaw rate sensor 64 that detects the yaw rate of the vehicle body A detection signal output from a speed sensor 65 that detects the speed of the vehicle, a detection signal output from a temperature sensor 66 that is disposed on a substrate (not shown) of the processing device 46 and detects a temperature, and the motor 10 The detection signal output from the current sensor 67 that detects the energized current and the output from the pair of Hall elements 23A and 23B. A phase predetermined processing in the sensor circuit 45 are, each pulse signal of phase B are inputted.

The winding position detection unit 51 calculates the rotational position of the belt reel 12 from the A-phase and B-phase pulse signals output from the rotation detection device 24, and uses this rotational position as the winding position.
In the following description, the rotation position (winding position) of the belt reel 12 is, for example, a state where the winding amount of the belt 5 by the belt reel 12 is zero (that is, the drawing amount is a predetermined maximum amount). The forward rotation direction of the belt reel 12 is a positive direction, and the value increases with the forward rotation of the belt reel 12, that is, the amount of winding of the belt 5 by the belt reel 12.

  The drawer detection unit 52 detects whether or not the belt 5 is pulled out from the belt reel 12 based on the rotational position of the belt reel 12 output from the winding position detection unit 51.

Based on the signal of the detected current I output from the current sensor 67, the overload determination unit 53 is overloaded with an excessive load with respect to rotation of the motor 10 in the forward rotation direction (that is, winding of the belt 5 by the belt reel 12). It is determined whether or not it is in a load state.
The overload determination unit 53 stores in advance a change threshold dIth for the current change amount dI and a current threshold Ith for the detection current I. The current change amount dI is less than the predetermined change threshold dIth and the detection current I Is less than a predetermined current threshold Ith, and if the result of this determination is “NO”, it is determined that an overload condition is present.

The clutch control unit 54 determines whether or not the belt 5 has been pulled out and is output from the pull-out detection unit 52 and the determination result of the overload state output from the overload determination unit 53. Control the clutch.
For example, the clutch control unit 54 instructs the clutch release execution when the pull-out detection unit 52 detects that the belt 5 is pulled out under a current condition in which the overload determination unit 53 does not determine the overload state. Furthermore, when the pull-out detection unit 52 detects further pull-out of the belt 5 after this clutch release execution instruction, the clutch engagement state is maintained.

  The delivery control unit 55 instructs the clutch control unit 54 to execute the release of the clutch when the withdrawal detection unit 52 detects the withdrawal of the belt 5 under a current condition in which the overload determination unit 53 does not determine the overload state. Further, when the pull-out detection unit 52 detects further withdrawal of the belt 5 after the instruction to execute the release of the clutch, the belt from the belt reel 12 is maintained in a state in which the clutch control unit 54 maintains the clutch connection state. 5 outputs a control signal instructing the execution of the delivery of 5.

  The motor control unit 56 responds to the rotational position of the belt reel 12 output from the winding position detection unit 51 and the control signal instructing execution of the feeding of the belt 5 output from the feeding control unit 55. The drive and stop timing and the target current are set and the energization to the motor 10 is controlled.

For example, the state where the motor 10 is energized so as to rotate in the forward rotation direction after time t0 shown in FIG. 7 (that is, the belt 5 is wound around the belt reel 12 by the rotational driving force of the motor 10). When the pulling operation of the belt 5 by the occupant is relatively abruptly executed with a force larger than the rotational driving force of the motor 10, the predetermined current threshold value Ith (handling determination) is accompanied with the stop of the motor 10. It becomes difficult to detect a current (lock current) that increases beyond the current threshold), and energization of the motor 10 is continued, and the motor 10 rotates in the reverse direction, but an external force in the pulling direction of the belt 5 acts. Due to the continued operation, the connection between the motor 10 and the belt reel 14 by the clutch in the power transmission mechanism 18 may be maintained.
In this case, since the rotational driving force of the motor 10 becomes a resistance against the pulling operation of the belt 5 by the occupant, the belt reel 14 is wound around the belt 5 by the elastic force of the winding spring 25, for example, after time t1. When the rotational driving force in the pull-out direction of the belt 5 input by the occupant is weakened, the belt is driven by the belt reel 12 when it is intended to release the connection between the motor 10 and the belt reel 14 by the clutch. 5 is executed, and the connection between the motor 10 and the belt reel 14 by the clutch is released.
However, at this time, since the motor 10 is driven to rotate in the forward rotation direction by continuing the energization, for example, after the time t2, the connection between the motor 10 and the belt reel 14 by the clutch is released, so that excessive When the belt 5 is pulled out by an occupant who determines that the belt 5 can be pulled out from the belt reel 14 without any resistance, the motor 10 and the belt reel 14 are immediately connected by the clutch. The rotational driving force of the motor 10 becomes a resistance to the pulling-out operation of 5, and for example, as shown at time t3, the belt 5 is locked out as if the emergency lock mechanism 20 was activated. Become.
At this time, that is, when the withdrawal detection unit 52 detects the withdrawal of the belt 5 under the current condition in which the overload judgment unit 53 does not determine the overload state, the clutch control unit 54 instructs the release of the clutch. Thus, the motor 10 is prevented from becoming a resistance against the pull-out of the belt 5 by the occupant.

  The vehicle seat belt device 1 according to the present embodiment has the above-described configuration. Next, the operation of the vehicle seat belt device 1, particularly, the operation when the tongue plate 8 is released from the buckle 9 is released. explain.

First, for example, in step S01 shown in FIG. 8, whether or not the buckle switch (buckle SW) 61 is OFF, that is, the detection signal output from the buckle switch (buckle SW) 61 is attached to the buckle 9. It is determined whether or not the OFF state is released.
If this determination is “NO”, the flow proceeds to the end, and the process ends.
On the other hand, if this determination is “YES”, the flow proceeds to step S 02.
In step S02, it is determined whether or not a predetermined time has elapsed since the buckle SW was turned off.
If the determination result is “NO”, the process of step S02 is repeated.
On the other hand, if the determination is “YES”, the flow proceeds to step S03.

In step S03, energization of the motor 10 with a predetermined current I0 is started, and winding of the belt 5 by the belt reel 12 is started.
In step S04, the timer is initialized by setting a predetermined initial value t0 to the timer value t of an appropriate timer, and time measurement by this timer is started.
In step S05, zero is set to the number of retries k.
In step S06, it is determined whether or not the number of retries k is less than the predetermined number N.
If this determination is “NO”, the flow proceeds to step S 17 described later.
On the other hand, if this determination is “YES”, the flow proceeds to step S07.

In step S07, the detection current I (= I (j), where j is an arbitrary natural number) output from the current sensor 67 in the current process is acquired.
In step S08, a value obtained by subtracting the detected current I (= I (j−1)) in the previous process from the detected current I (= I (j)) in the current process (I ( j) -I (j-1)) is set as the current change amount dI.
In step S09, it is determined whether or not the current change amount dI is less than the change amount threshold dIth and the current detection current I (= I (j)) is less than the current threshold Ith.
If this determination is “NO”, the flow proceeds to step S 10.
On the other hand, if this determination is “YES”, the flow proceeds to step S 12 described later.

In step S10, a hook determination is made to determine that the motor 10 is in an overload state in which an excessive load is applied to the rotation in the forward rotation direction of the motor 10 (that is, the winding of the belt 5 by the belt reel 12). Stop energizing the unit and wait until a predetermined time elapses.
In step S11, a value (k + 1) obtained by adding “1” to the retry count k is newly set as the retry count k, and the process returns to step S06 described above.

In step S12, whether or not the difference between the rotational position of the belt reel 12 in the previous process and the rotational position of the belt reel 12 in the current process is other than zero, that is, the rotational angle of the motor 10 is the last time. It is determined whether or not there is a change between the process of this time and the current process.
If this determination is “YES”, the flow proceeds to step S 14 described later.
On the other hand, if this determination is “NO”, the flow proceeds to step S 13.

In step S13, it is determined whether or not a value (t−t0) obtained by subtracting the predetermined initial value t0 from the timer value t of the timer at this time is equal to or longer than the predetermined time ta.
If this determination is “NO”, the flow returns to step S 12 described above.
On the other hand, if the determination is “YES”, the flow proceeds to step S10.

In step S14, it is determined whether the rotation direction of the motor 10 is the normal rotation direction, that is, the winding direction of the belt 5 by the belt reel 12.
If this determination is “NO”, the flow proceeds to step S 15 to perform a drawer detection process described later.
On the other hand, if this determination is “YES”, the flow proceeds to step S 16, where it is determined whether or not the belt 5 has been wound on the belt reel 12 to a predetermined storage position.
If this determination is “NO”, the flow returns to step S 06 described above.
On the other hand, if this determination is “YES”, the flow proceeds to step S 17, where the energization of the motor 10 is stopped and the series of processing is ended.

Hereinafter, the drawer detection process in step S15 will be described.
First, for example, in step S21 shown in FIG. 9, it is determined whether or not the drawing speed V of the belt 5 from the belt reel 12 is less than a predetermined speed V1.
If the determination result is “NO”, it is determined that the withdrawal of the belt 5 from the belt reel 12 is further continued, and the process proceeds to Step S24 described later.
On the other hand, if this determination is “YES”, the flow proceeds to step S22.

In step S22, the motor 10 is energized for a predetermined time Ts with the predetermined first current I1 so as to rotate the motor 10 in the reverse rotation direction.
The first current I1 is such a value that the rotational driving force in the reverse direction of the motor 10 becomes larger than the rotational driving force accompanying the pulling-out operation of the belt 5 by the occupant. The connection between the motor 10 and the belt reel 14 by the clutch is released.
In step S23, energization of the motor 10 is stopped, the process proceeds to the end, and the series of processes is terminated.

In step S24, the motor 10 is driven to rotate in the reverse direction to start energization of the motor 10 with a predetermined second current I2 (≧ I1) equal to or greater than the predetermined first current I1. The belt 5 is sent out from the belt reel 14 by the rotational driving force of 10.
In step S25, the timer is initialized by setting a predetermined initial value t0 to the timer value t of an appropriate timer, and time measurement by this timer is started.
In step S26, it is determined whether or not the drawing speed V is less than a predetermined speed V2 (for example, V2 ≦ V1) equal to or lower than the predetermined speed V1, for example.
When the determination result is “YES”, the rotational driving force accompanying the pulling-out operation of the belt 5 by the occupant is smaller than the rotational driving force of the motor 10 in the reverse direction, so that the motor 10 and the belt reel 14 by the clutch are reduced. It is determined that the connection to is released, and the process proceeds to step S23 described above.
On the other hand, if this determination is “NO”, the flow proceeds to step S 27.

In step S27, it is determined whether or not a value (t−t0) obtained by subtracting the predetermined initial value t0 from the timer value t of the timer at this time is equal to or longer than the predetermined time ta.
If this determination is “YES”, the flow proceeds to step S 23 described above.
On the other hand, if this determination is “NO”, the flow proceeds to step S 28.
In step S28, it is determined whether or not the feed amount X of the belt 5 from the belt reel 12 is larger than the predetermined feed amount Xth.
If this determination is “YES”, the flow proceeds to step S 23 described above.
On the other hand, if this determination is “NO”, the flow returns to step S 26 described above.

As described above, according to the vehicle seat belt device 1 according to the present embodiment, for example, the winding of the belt 5 by the belt reel 14 is assisted by the driving force of the motor 10, or the winding spring 25 In the state in which the belt 5 is being wound by the belt reel 14 by the elastic force of the belt, in the pulling direction at a speed higher than the winding speed by the driving force of the motor 10 or the elastic force of the winding spring 25 by the operation of the occupant. When the belt 5 is pulled out and the belt 5 is remounted, an increase in the current flowing through the motor is not detected, and even when the overload determination is not performed, this belt 5 is detected. Then, the connection between the motor 10 and the belt reel 14 by the clutch is released, and the motor 10 is stopped, thereby It is possible to prevent an excessive load (resistance) occurs for withdrawal of the belt 5 by.
Thereby, for example, the overload determination condition, that is, the current threshold value Ith (handling determination current threshold value) is decreased to set the overload determination so that the overload determination is easily performed. It is possible to prevent the determination and the release of the connection between the motor 10 and the belt reel 14 by the clutch and the stop of the motor 10 from being executed.

  In the embodiment described above, in the pull-out detection process shown in steps S21 to S28, depending on the determination result of whether or not the pull-out speed V of the belt 5 from the belt reel 12 is less than the predetermined speed V1. The energization for a predetermined time Ts with the predetermined first current I1 or the energization with the predetermined second current I2 (≧ I1) equal to or greater than the predetermined first current I1 is selected and executed. For example, as in the modification of the above-described embodiment shown in FIG. 10, first, after energization is performed for a predetermined time Ts with a predetermined first current I1, the drawing speed V of the belt 5 from the belt reel 12 is predetermined. It may be determined whether or not the speed is less than V1.

In this modification, first, in step S31 shown in FIG. 10, the motor 10 is energized for a predetermined time Ts with a predetermined first current I1 so as to be rotationally driven in the reverse direction.
In step S32, it is determined whether or not the drawing speed V of the belt 5 from the belt reel 12 is less than a predetermined speed V1.
When the determination result is “NO”, it is determined that the belt 5 is further pulled out from the belt reel 12 by the occupant while the belt 5 is being fed from the belt reel 12 by the reverse rotation of the motor 10. Then, it progresses to step S34 mentioned later.
On the other hand, if the determination is “YES”, the flow proceeds to step S33.
In step S33, energization of the motor 10 is stopped, the process proceeds to the end, and the series of processes is terminated.

In step S34, energization of the motor 10 with a predetermined second current I2 (≧ I1) equal to or greater than the predetermined first current I1 is started so as to rotate the motor 10 in the reverse rotation direction. The belt 5 is sent out from the belt reel 14 by the rotational driving force of 10.
In step S35, the timer is initialized by setting a predetermined initial value t0 to the timer value t of an appropriate timer, and time measurement by this timer is started.
In step S36, it is determined whether or not the drawing speed V is less than a predetermined speed V2 (for example, V2 ≦ V1) that is equal to or lower than the predetermined speed V1, for example.
When the determination result is “YES”, the rotational driving force accompanying the pulling-out operation of the belt 5 by the occupant is smaller than the rotational driving force of the motor 10 in the reverse direction, so that the motor 10 and the belt reel 14 by the clutch are reduced. It is determined that the connection to is released, and the process proceeds to step S33 described above.
On the other hand, if this determination is “NO”, the flow proceeds to step S 37.

In step S37, it is determined whether or not a value (t−t0) obtained by subtracting the predetermined initial value t0 from the timer value t of the timer at this time is equal to or longer than the predetermined time ta.
If this determination is “YES”, the flow proceeds to step S 33 described above.
On the other hand, if this determination is “NO”, the flow proceeds to step S38.
In step S38, it is determined whether or not the feed amount X of the belt 5 from the belt reel 12 is larger than the predetermined feed amount Xth.
If this determination is “YES”, the flow proceeds to step S 33 described above.
On the other hand, if this determination is “NO”, the flow returns to step S 36 described above.

  According to this modification, when the withdrawal of the belt 5 is detected under a current condition where the overload determination is not performed, the withdrawal of the belt 5 by the belt reel 12 is performed by assisting the withdrawal by the rotational driving force of the motor 10. Even if the increase in the current flowing through the motor 10 is not detected when the belt 5 is pulled out by the occupant during winding, the occupant's intention can be appropriately reflected in the behavior of the motor 10.

  In the embodiment and the modification described above, in the pull-out detection process, whether or not the pull-out speed V of the belt 5 from the belt reel 12 is less than the predetermined speed V1, and the pull-out speed V is equal to or less than the predetermined speed V1. However, the present invention is not limited to this. For example, instead of the pull-out speed V, a determination process based on the pull-out amount of the belt 5 from the belt reel 12 may be executed. . That is, in this case, in step S21 and step S32 described above, for example, it is determined whether or not the pull-out amount of the belt 5 from the belt reel 12 per predetermined time is less than the predetermined pull-out amount X1. In step S26 and step S36 described above, for example, it is determined whether or not the amount of pulling out of the belt 5 from the belt reel 12 per predetermined time is less than a predetermined pulling amount X2 that is equal to or smaller than a predetermined pulling amount X1.

1 is a schematic configuration diagram of a vehicle seat belt device according to an embodiment of the present invention. 1 is a schematic configuration diagram of a vehicle seat belt device according to an embodiment of the present invention. It is a principal part longitudinal cross-sectional view of the retractor which concerns on one Embodiment of this invention. It is a disassembled perspective view of the retractor which concerns on one Embodiment of this invention. It is a schematic block diagram of the rotation detection apparatus which concerns on one Embodiment of this invention. A phase and B phase pulse signal waveforms output from each Hall element of the rotation detection device according to an embodiment of the present invention, a numerical value of each phase signal level, and a numerical value of each phase It is a figure which shows the numerical value obtained by adding. It is a graph which shows the example of the correspondence of the electric current supplied to the motor which concerns on one Embodiment of this invention, and the amount of feeding of the belt from a belt reel. It is a flowchart which shows operation | movement of the vehicle seatbelt apparatus which concerns on one Embodiment of this invention. It is a flowchart which shows the process of drawer | drawing-out detection which concerns on one Embodiment of this invention. It is a flowchart which shows the process of the drawer | drawing-out detection which concerns on the modification of embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vehicle seat belt apparatus 5 Belt 10 Motor 14 Belt reel 24 Rotation detection apparatus (position sensor)
25 Winding spring 46 Processing device (control unit)
51 Winding position detector (position sensor)
53 Overload determination unit (overload determination means)
54 Clutch control unit (clutch release means)
55 Sending control unit (feeding means)

Claims (3)

A belt reel that winds the belt;
Biasing means for biasing the belt reel in the winding direction;
A motor for winding the belt by transmitting a driving force to the belt reel;
A clutch mechanism for connecting / disconnecting transmission of driving force between the motor and the belt reel by a rotational difference between the belt reel and the motor;
A vehicle seat belt device comprising: a control unit that controls an energization amount to the motor;
A position sensor for detecting the position of the belt by detecting the rotational position of the belt reel;
The controller is
Overload determination means for performing overload determination based on the current flowing to the motor;
Clutch release means for instructing execution of release of the clutch mechanism when the withdrawal of the belt is detected based on a detection signal output from the position sensor under a current condition in which the overload determination by the overload determination means is not executed. A vehicle seat belt device. The control unit includes delivery means for delivering the belt while maintaining the connected state of the clutch mechanism when the withdrawal of the belt is detected after the release execution instruction by the clutch release means. The vehicle seat belt device according to claim 1. A belt reel that winds the belt;
Biasing means for biasing the belt reel in the winding direction;
A motor for winding the belt by transmitting a driving force to the belt reel;
A clutch mechanism for connecting / disconnecting transmission of driving force between the motor and the belt reel by a rotational difference between the belt reel and the motor;
A vehicle seat belt device comprising: a control unit that controls an energization amount to the motor;
A position sensor for detecting the position of the belt by detecting the rotational position of the belt reel;
The controller is
Overload determination means for performing overload determination based on the current flowing to the motor;
When the belt is pulled out based on a detection signal output from the position sensor under a current condition in which the overload determination by the overload determination unit is not performed, the belt is maintained while the clutch mechanism is connected. A vehicular seat belt device comprising a feeding means for performing the feeding of the vehicle.

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