JP6968615B2 - Sliding door switchgear - Google Patents

Description

The present invention relates to a sliding door opening / closing device .

The following Patent Document 1 discloses a power window control device that detects the rotation speed of a motor that drives a window glass.

These power window control devices generally detect the rotation speed of the motor based on the pulse period of the pulse signal generated in response to the rotation of the motor. Specifically, the power window control device averages the pulse periods of the number of pulses for one rotation of the motor in order to suppress the variation in the rotation speed of the motor, and obtains the rotation speed of the motor.

Japanese Unexamined Patent Publication No. 2000-314269

However, since the rotation speed of the motor is obtained by averaging the pulse periods up to a predetermined number of times before the present, when the rotation speed of the motor gradually decreases or increases, it becomes the actual rotation speed of the motor. The difference becomes large. Therefore, it is not possible to accurately detect the rotation speed of the motor.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a slide door opening / closing device capable of more accurately detecting the rotation speed of a motor.

One aspect of the present invention is a slide door opening / closing device having a speed detection device for detecting the speed of a slide door for a vehicle, the roller assembly provided on the slide door, a cable connected to the roller assembly, and the like. A drum around which the cable is wound, a motor for rotationally driving the drum, and a guide rail for guiding the roller assembly are provided, and the guide rail is formed on the front side of the vehicle and curved toward the vehicle interior side. with a certain curvature, and the straight portion formed on the rear side of the vehicle, wherein the speed detection device includes a rotation sensor for outputting a pulse signal according to the rotation of the front liver over motor, the pulse period of the pulse signal The speed detection unit includes a cycle detection unit that detects the rotation speed of the motor from a predetermined number of pulse cycles, and the speed detection unit includes the curved portion of the slide door according to the count number of the pulse signal. If it is determined to enter the a speed detecting device and detects the rotation speed of said decreasing the pre Symbol predetermined number motor.

One aspect of the present invention is the above-mentioned slide door opening / closing device , and when the pulse period exceeds a predetermined range, the speed detecting unit reduces the predetermined number to detect the rotation speed of the motor. ..

One aspect of the present invention is the above-mentioned slide door opening / closing device , in which the rotation speed of the motor is an average value of the predetermined number of the pulse cycles.

As described above, according to the present invention, the rotational speed of the motor can be detected more accurately.

It is a side view which shows the one-box type vehicle provided with the switchgear 21 for a vehicle which concerns on one Embodiment of this invention. It is an enlarged view which shows the detail of the mounting part of the slide door 13 which concerns on one Embodiment of this invention. It is a figure which shows an example of the schematic structure in the control system of the switchgear 21 for a vehicle which concerns on one Embodiment of this invention. It is a figure which shows an example of the schematic structure of the control device 31 which concerns on one Embodiment of this invention. It is a figure explaining the detection method of the rotation speed V of the motor 25 in the speed detection unit 320 which concerns on one Embodiment of this invention. It is a figure explaining the operation flow of the control device 31 which concerns on one Embodiment of this invention.

Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention to which the claims are made. Also, not all combinations of features described in the embodiments are essential to the means of solving the invention.

Hereinafter, the speed detection device according to the embodiment of the present invention will be described with reference to the drawings.

Hereinafter, the vehicle opening / closing device 21 including the speed detection device according to the present embodiment will be described with reference to the drawings. FIG. 1 is a side view showing a one-box type vehicle provided with the vehicle opening / closing device 21 of the present embodiment. FIG. 2 is a top view of the slide door 13 in the present embodiment, and is an enlarged view showing details of a mounting portion of the slide door 13.

As shown in FIGS. 1 and 2, the vehicle 11 includes a slide door 13, guide rails 14, 16, 17, and a vehicle opening / closing device 21.

As shown in FIG. 1, the vehicle 11 is a one-box type passenger car, and a sliding door 13 is provided on a side portion of the vehicle body 12. The sliding door 13 is an example of the "opening / closing body" of the present invention. For example, the "opening and closing body" of the present invention may be a tailgate.

The slide door 13 is guided by a guide rail (guide member) 14 fixed to the side portion of the vehicle body 12 and can be opened and closed between the fully closed position shown by the solid line and the fully open position shown by the alternate long and short dash line in FIG. Is. Therefore, when the occupant gets on and off, the cargo is loaded and unloaded, and the like, the slide door 13 is opened to a desired opening degree and used. Further, the slide door 13 is provided with a handle 34 as an open / close switch in order to instruct the opening / closing operation of the slide door 13.

As shown in FIG. 2, the slide door 13 is provided with a roller assembly 15. The slide door 13 moves in the front-rear direction of the vehicle 11 by the roller assembly 15 being guided by the guide rail 14.

The guide rail 14 includes a curved portion 14a, a straight portion 14b, a reversing pulley 18, and a reversing pulley 19.

The curved portion 14a is formed on the vehicle front side of the guide rail 14. The curved portion 14a has a shape that curves toward the vehicle interior side. The slide door 13 is closed in a state of being pulled inside the vehicle body 12 so as to be fitted on the same surface as the side surface of the vehicle body 12 by guiding the roller assembly 15 to the curved portion 14a. The straight portion 14b is formed at a position rearward of the vehicle with respect to the curved portion 14a. The straight portion 14b has a shape parallel to the side portion of the vehicle body 12.

The roller assembly 15 is provided not only at the portion shown in FIG. 2 but also at the upper and lower portions (upper portion / lower portion) of the front end portion of the slide door 13. Guide rails 16 and guide rails 17 are provided at the upper and lower portions of the opening of the vehicle body 12 corresponding to the roller assemblies 15 provided at the upper and lower portions (upper portion and lower portion) of the front end portion of the slide door 13. Therefore, the sliding door 13 is supported by the vehicle body 12 at a total of three places.
The reversing pulleys 18 and 19 are provided at both ends of the guide rail 14, respectively.

The vehicle opening / closing device 21 is a device that automatically opens / closes the sliding door 13.
The vehicle switchgear 21 includes a drive unit 22 and a cable 23 (cable 23a, cable 23b).
The drive unit 22 is arranged inside the vehicle body 12 adjacent to a substantially central portion of the guide rail 14 in the vehicle front-rear direction.
The cable 23a and the cable 23b are connected to the roller assembly 15 from the rear side and the front side of the vehicle, respectively. In the drive unit 22, the slide door 13 is opened or closed by pulling one of the cables 23a and 23b.

FIG. 3 is a diagram showing an example of a schematic configuration in the control system of the vehicle switchgear 21 according to the present embodiment.

The vehicle switchgear 21 includes a motor 25, a speed reducer 26, a drum 28, a rotation sensor 33, and a control device 31. The control device 31 is an example of the "speed detection device" of the present invention.

The motor 25 is a drive source that drives the slide door 13 to open and close. For example, the motor 25 is a motor that can rotate in both forward and reverse directions, such as a three-phase brushless motor. The motor 25 is rotationally driven based on the drive signal supplied from the control device 31.

The speed reducer 26 is fixed to the motor 25, and the rotation of the motor 25 is reduced to a predetermined rotation speed by the speed reducer 26. Therefore, the rotation of the motor 25 is decelerated to a predetermined rotation speed by the speed reducer 26 and output from the output shaft 27.

A cylindrical drum 28 having a spiral guide groove (not shown) formed on the outer peripheral surface is fixed to the output shaft 27. A cable 23 is wound around the drum 28 a plurality of times along the guide groove. Therefore, when the motor 25 operates and the drum 28 is driven by the motor 25 to rotate, the slide door 13 opens and closes. That is, when the motor 25 rotates in the forward direction, the drum 28 rotates, for example, in the counterclockwise direction. As a result, the rear side of the cable 23 is wound around the drum 28, so that the slide door 13 moves in the opening direction while being pulled by the cable 23. On the other hand, when the motor 25 reverses, the drum 28 rotates, for example, in the clockwise direction. As a result, the vehicle front side of the cable 23 is wound around the drum 28, so that the slide door 13 moves in the closing direction while being pulled by the cable 23.

As described above, the slide door 13 is connected to the motor 25 via the cable 23, the drum 28, the output shaft 27, and the like, and is driven to open and close by the motor 25. The speed reducer 26 may be provided with a clutch mechanism for interrupting the power transmission path between the motor 25 and the output shaft 27, and the clutch mechanism may be switched to the cutoff state when the slide door 13 is manually opened and closed. .. Further, a tensioner may be provided between the drum 28 and the slide door 13 to remove the slack of the cable 23 and maintain the cable tension within a certain range.

The rotation sensor 33 detects the position of the slide door 13. For example, the rotation sensor 33 is a magnetic rotary encoder equipped with a Hall IC. For example, a sensor magnet 32 having a large number of magnetic poles magnetized in the circumferential direction is fixed to the output shaft 27. The hall IC 32a, the hall IC 32b, and the hall IC 32c, which are rotation sensors 33, are arranged so as to be close to the position facing the sensor magnet 32. The hall IC 32a, the hall IC 32b and the hall IC 32c are arranged with a predetermined phase difference from each other. Therefore, in the rotation sensor 33, the change in the magnetic flux density detected by the rotation of the drum 28 and the sensor magnet 32 passing in front of the hole IC 32a, the hole IC 32b, and the hole IC 32c is used as an electric signal, and the three phases (U phase) are different from each other. , V phase and W phase) alternation signals. The output values of the rotation sensor 33 are High and Low depending on whether or not the value of the alternating signal of each phase exceeds a predetermined value (that is, the strength of the magnetic field received by the rotation sensor 33 exceeds the predetermined strength). It is converted into a binary digital signal (pulse signal) that changes to. The rotation sensor 33 outputs a U-phase pulse signal, a V-phase pulse signal, and a W-phase pulse signal as pulse signals of each phase to the control device 31.

The slide door 13 is provided with a handle 34 having a function as an open / close switch on the inside side and the outside side of the vehicle interior, respectively. The handle 34 is connected to the control device 31. When the handle 34 is operated by an occupant or the like, the handle 34 outputs an open / close command signal corresponding to the operation to the control device 31. That is, when the handle 34 is operated to the open side by an operator such as an occupant, the handle 34 outputs a command signal instructing to open the slide door 13 to the control device 31. The handle 34 outputs a command signal instructing the closing of the slide door 13 to the control device 31 when the handle 34 is operated to the closed side by an operator such as an occupant. When the control device 31 acquires the open / close command signal supplied from the handle 34, the control device 31 controls the motor 25 to rotate forward or reverse based on the open / close command signal. As a result, the control device 31 can operate the slide door 13 in the open direction or the closed direction. That is, the operator can automatically open and close the slide door 13 by operating the handle 34.

The control device 31 obtains the rotation speed of the motor 25 from the period of the pulse signal. Then, the control device 31 controls the motor 25 so that its rotation speed becomes constant.

FIG. 4 is a diagram showing an example of a schematic configuration of the control device 31 according to the present embodiment.
The control device 31 includes a cycle detection unit 310, a speed detection unit 320, and a drive unit 330.

When the opening / closing operation of the slide door 13 by the command signal is started (or when the pulse signal appears), the cycle detection unit 310 has the cycle of the pulse signal supplied from the rotation sensor 33 (hereinafter referred to as “pulse cycle”). T is detected every time a pulse signal is acquired from the rotation sensor 33. For example, the cycle detection unit 310 detects the pulse cycle T from the acquisition interval of the pulse signal from the rotation sensor 33. Therefore, for example, when the sensor magnet 32 for 16 poles is fixed to the output shaft 27, the cycle detection unit 310 detects 16 pulse cycles T for each rotation of the drum 28. ..

The speed detection unit 320 detects the rotation speed V of the motor 25 from the pulse period T having a predetermined number of data N (predetermined number). Here, the pulse cycle T having the number of data N is the pulse cycle T from the latest pulse cycle T to N before the pulse cycle T acquired by the cycle detection unit 310. As described above, the number of data N is the number of data of the pulse period T required to obtain the rotation speed V.
However, the speed detection unit 320 does not set the number of data N to a fixed value, but sets it to a changed value that decreases according to the latest pulse period T.
Hereinafter, a method of detecting the rotation speed V of the motor 25 in the speed detection unit 320 will be described with reference to FIG.

For example, the speed detection unit 320 averages the pulse period T of the number of pulses for one rotation of the motor 25 (drum 28) to obtain the rotation speed V. Here, in the present embodiment, 16 pulse signals are output from the rotation sensor 33 for each rotation of the drum 28. Therefore, the speed detection unit 320 averages the latest 16 pulse periods T, with the number of data N being "16", and obtains the _{average pulse period Tave.}

Specifically, the speed detector 320, when the current pulse period Tn, as shown in equation (1), 16 pulse period from the pulse period T _n to the pulse period T _n-15 The average pulse period _Tave is obtained by averaging.
Average pulse period T _ave = (T _n + T _n-1 + ... T _n-15 ) / 16 ... (1)

However, as shown in FIG. 5, when the current pulse period _Tn exceeds a predetermined range (range below the threshold value Tx and above the threshold value Ty (<Tx)), the speed detection unit 320 determines the number of data N. The rotation speed V is detected by decreasing the value. For example, the speed detector 320, if the current pulse period T _n exceeds the threshold Tx is a predetermined number value obtained by subtracting the (subtraction value) X from the current data number N new number of data N' And. Then, the speed detector 320, a pulse period T of the newly determined number of pieces of data N'are averaged to obtain an average pulse period _T'ave. That is, the speed detector 320, if the current pulse period T _n exceeds the threshold Tx is to reduce the number of data of pulse period T to average in order to obtain an average pulse period T _ave, in its reduced and the number of data determine the average pulse period _T'ave.

For example, as shown in FIG. 5, when the current data number N is "16", the speed detection unit 320, if the current pulse period T _n exceeds the threshold Tx is shown in Equation (2) as such, by changing the number of data to half the value of the current data number n, determines the average pulse period _T'ave eight pulse period from the pulse period T _n to the pulse period T _n-7 averages ..
Average pulse period _{T'ave = (T n + T} n-1 + ... T n-7) / 8 ... (2)

The drive unit 330 controls the drive of the motor 25 so that the rotation speed V detected by the speed detection unit 320 becomes a target value.

Hereinafter, the operation of the control device 31 according to the present embodiment will be described with reference to FIG. FIG. 6 is a diagram illustrating an operation flow of the control device 31 according to the present embodiment.

The cycle detection unit 310 detects the pulse cycle T each time the pulse signal supplied from the rotation sensor 33 is acquired (step S101).
Speed detecting unit 320, each time the pulse signal in a cycle detecting section 310 is acquired, determines whether the current pulse period _{T n} exceeds the threshold value Tx (step S102). Speed detecting unit 320, when judging that the current pulse period _{T n} does not exceed the threshold value Tx, the current pulse period of the data number _N Tn~T _n- the _(N-1) by averaging the reference, The average pulse period _Tave is calculated (step S103).

On the other hand, the speed detector 320, in step S102, if it is determined that the current pulse period T _n exceeds the threshold Tx, the pulse period of the current small number of data N'than the number of data N based on the Tn~T _n- and _(N'-1) are averaged to calculate the average pulse period _T'ave (step S104). That is, the speed detector 320, in step S102, if it is determined that the current pulse period T _n exceeds the threshold Tx is to reduce the number of data of pulse period for averaging a predetermined number X, the number of data reduced the in by averaging the pulse period, and calculates the average pulse period _T'ave.

The speed detection unit 320 obtains the rotation speed V of the motor 25 from the calculated averaging period (step S105). That is, the speed detection unit 320, when judging that the current pulse period T _n does not exceed the threshold value Tx calculates the rotational speed V from the average pulse period T _ave. On the other hand, the speed detection unit 320, when judging that the current pulse period T _n exceeds the threshold Tx calculates the rotational speed V from the average pulse period _T'ave.

Next, the action and effect of this embodiment will be described.
When the conventional speed detection device detects the rotation speed of the motor 25 that drives the opening / closing body for the vehicle, in order to suppress the variation in the rotation speed of the motor 25, a pulse period of a fixed number of data (for example, for example). The average pulse period is obtained by averaging (the pulse cycle of the number of pulses for one rotation of the motor 25), and the rotation speed of the motor 25 is detected from the averaging cycle. Here, for example, when the vehicle is stopped on a slope, gravity generates a force on the opening / closing body of the sliding door or the tailgate in a direction parallel to the slope. Therefore, the actual rotation speed (actual speed) of the motor 25 that drives the opening / closing body gradually decreases or increases, and the pulse period changes significantly. However, when the rotation speed of the motor 25 is detected, a plurality of pulse cycles are averaged in order to suppress the variation in the rotation speed of the motor, and the motor is derived from the averaged pulse period (corresponding to the _{average pulse period Tave).} It is necessary to obtain the rotation speed of 25. Therefore, in the conventional speed detection device, _{the difference ΔT between the current pulse period Tn} and the averaged pulse period (average pulse period _Tave ) becomes large, and the difference between the rotational speed of the motor 25 and the actual speed becomes large. growing. As a result, the rotation speed of the motor 25 cannot be accurately detected.

On the other hand, the speed detection unit 320 according to the present embodiment obtains _{an average pulse period Data} when the actual rotation speed (actual speed) of the motor 25 for driving the open / close body decreases or increases by a predetermined value or more. to reduce the number of data pulse period T for averaging to obtain an average pulse period _T'ave the number of data reduced the. Accordingly, speed detector 320 can be made smaller than before the difference ΔT between the averaged pulse period and the current pulse period T _n (average pulse period _T'ave). Therefore, the speed detector 320, that the average pulse period _T'ave determining the rotational speed of the motor 25, can also be reduced compared with the conventional difference between the rotational speed and the actual speed of the motor 25, the rotation of the motor 25 The speed can be detected more accurately. Note that if the actual speed of the motor 25 which drives the opening and closing body is increased above a predetermined value, a case where the current pulse period T _n exceeds the threshold Tx.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

(Modification 1) In the above embodiment, the speed detection unit 320 has reduced the number of data N when the current pulse period T _n exceeds the threshold Tx, the present invention is not limited thereto. For example, the speed detecting unit 320 may reduce the data number N when the current pulse period _{T n} below the threshold Ty (<Tx). Incidentally, the above-described, and when the actual speed of the motor 25 which drives the opening and closing body is decreased by more than a predetermined value is if the current pulse period T _n below the threshold Ty.

(Modification 2) In the above embodiment, when the current pulse period _Tn is out of the predetermined range, the speed detection unit 320 subtracts a preset number (subtraction value) X from the current number of data N. The value obtained is set to the new number of data N', but the present invention is not limited to this. For example, the speed detection unit 320 may change the subtraction value X according to the pulse Tn. More specifically, for example, the speed detector 320, if the current pulse period T _n exceeds the threshold Tx is the subtracted value X determined in accordance with the value of (Tn-Tx), subtraction in which the determined X may be subtracted from the current number of data to obtain a new number of data N'. Further, for example, the speed detector 320, if the current pulse period T _n below the threshold Ty is (Ty-Tn) value subtracted value X determined in accordance with the current subtraction X that has the determined The new number of data N'may be obtained by subtracting from the number of data of. Thus, the speed detector 320, may be varied depending on the current pulse period T _n the amount of reducing the number of data.

(Modification 3) In the above embodiment, the velocity detection unit 320 reduces the number of data of the pulse cycle T for _{obtaining the average pulse cycle Tave when the current pulse cycle Tn} is out of the predetermined range. , The present invention is not limited to this. For example, in response to the sliding door 13 entering the curved portion 14a, the speed detecting unit 320 may reduce the number of data of the pulse period T for _{obtaining the average pulse period Tave.} This is because when the slide door 13 enters the curved portion 14a, the speed of the slide door 13, that is, the actual speed of the motor 25 decreases. The fact that the slide door 13 has entered the curved portion 14a can be determined by the number of pulse signal counts after the slide door 13 operates.

(Modification 4) In the above embodiment, the speed detection unit 320 _{obtains the} rotation speed from the average pulse period Tave, but the present invention is not limited to this. For example, the speed detection unit 320 may obtain a representative value such as a median value or a mode value from the pulse period of the number of data N or N', and obtain the representative value or the rotation speed of the motor 25.

As described above, the control device 31 (speed detection device) reduces the number of data (predetermined number) of the pulse cycle required for calculating the rotation speed of the motor 25 according to the detected pulse cycle. As a result, the control device 31 can reduce the difference between the detected rotation speed of the motor 25 and the actual speed, and suppress the deterioration of the speed followability. As a result, the control device 31 can more accurately detect the rotation speed of the motor 25.

11 Vehicle 13 Sliding door (opening and closing body)
25 Motor 31 Control device (speed detection device)
33 Rotation sensor 310 Period detection unit 320 Speed detection unit 330 Drive unit

Claims (3)

A sliding door opening / closing device having a speed detecting device for detecting the speed of a sliding door for a vehicle.
The roller assembly provided on the sliding door and
With the cable connected to the roller assembly,
The drum around which the cable is wound and
The motor that drives the drum to rotate and
The guide rail that guides the roller assembly and
Equipped with
The guide rail is
A curved part that is formed on the front side of the vehicle and curves toward the interior of the vehicle,
The straight part formed on the rear side of the vehicle and
Equipped with
The speed detection device is
A rotation sensor for outputting a pulse signal according to the rotation of the front liver over data,
A cycle detection unit that detects the pulse cycle of the pulse signal,
A speed detector that detects the rotational speed of the motor from a predetermined number of pulse periods, and
Equipped with
The speed detecting section, a slide to the case where the entry into the curved portion is determined, characterized in that the previous SL to reduce the predetermined number for detecting the rotational speed of the motor of the sliding door by counting the number of the pulse signal Door opening and closing device . The slide door opening / closing device according to claim 1, wherein the speed detecting unit detects the rotational speed of the motor by reducing the predetermined number when the pulse period exceeds a predetermined range. The slide door opening / closing device according to claim 1, wherein the rotation speed of the motor is an average value of the predetermined number of the pulse cycles.

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