JP6022961B2 - Vehicle door handle operating force measurement device - Google Patents

Description

  The present invention relates to a technique of an operation force measuring device that is an apparatus for measuring an operation force acting on a door handle when a door of a vehicle such as an automobile is opened and closed.

In recent years, attention has been paid to an operation feeling when a person opens and closes a door of a vehicle as one of the factors that determine the quality of a vehicle represented by an automobile or the like.
In order to quantitatively evaluate such an operation feeling of the door, it is necessary to measure a force (hereinafter referred to as an operating force) that acts on the door handle by a human operation.
Further, in measuring the operating force acting on the door handle, it is necessary to measure at least each component force in the normal direction, the vertical direction and the height direction of the door.

Conventionally, as a technique for measuring an operation force acting on a door handle of a vehicle door, for example, a technique disclosed in Patent Document 1 shown below is disclosed and publicly known.
In the prior art disclosed in Patent Document 1, a rotational torque is detected by a rotation sensor disposed in a door hinge portion of an automobile door, and a door opening / closing operation force is calculated from the detected rotational torque.

JP-A-6-328940

  However, in the related art according to Patent Document 1, although the force acting on the entire door can be measured, the operating force acting on the door handle alone cannot be measured.

  Further, for example, when a load sensor (such as a load cell) for measuring an operating force is directly attached to the door handle, when the person operates the door handle, Since human gripping force and the like also act, it is difficult to accurately measure only the operating force.

Furthermore, for example, when the operating force acting on the door handle is to be measured with a single load sensor (load cell), a moment acts on the load cell, but with a load cell large enough to be attached to the door handle, There was a problem that the moment input was not allowed (the load cell was broken by the moment input).
For this reason, conventionally, it has not been possible to configure an operation force measuring device using a small load sensor.

  The present invention has been made in view of such a problem of the present situation, and an operation force measuring device for a vehicle door handle capable of accurately measuring an operation force acting on the door handle using a small sensor. The purpose is to provide.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, according to the first aspect of the present invention, a measurement handle that is attached to a door handle of a door of a vehicle and forms a part for inputting an operation force to the door handle, and a door that detects a rotation angle of the door. An angle measuring device, and an arithmetic unit that calculates the operating force input to the door handle via the measurement handle, the measurement handle fixing the measurement handle to the door handle. An attachment part that is a part for the operation part, an operation part that is a part for a person to input an operation force, and a part that connects the attachment part and the operation part. comprising a plurality of load sensors, and by the arithmetic unit, based on the measured values of the plurality of load sensors, the operation force calculated in the rotation angle measured by said door goniometer It is intended to.

  According to a second aspect of the present invention, the apparatus further comprises a door handle displacement amount measuring device that detects a displacement amount of the door handle with respect to the door, and the plurality of loads are calculated by the calculator based on the measurement values of the door handle displacement amount measuring device. It corrects the measured value of the sensor.

  According to a third aspect of the present invention, the measurement handle includes a first mode for detecting an operation force acting on the door handle when the door is closed, and an operation acting on the door handle when the door is opened. The second mode for detecting the force is configured to be changeable.

  As effects of the present invention, the following effects can be obtained.

  According to the first aspect, while using a small sensor, the input of a moment can be allowed, the influence of a person's gripping force and the like can be eliminated, and the operating force acting on the door handle can be measured with high accuracy.

  According to the second aspect, the operation force acting on the door handle can be measured with higher accuracy.

According to the third aspect, the measurement handle can be configured by using a general-purpose sensor.
As a result, an operation force measuring device with an inexpensive and simple configuration can be realized.

The schematic diagram which shows the whole structure of the operating force measuring apparatus of the door handle for motor vehicles which concerns on 1st embodiment of this invention. The schematic diagram which shows the relationship between the door at the time of door opening and closing, and a door handle. 1 is a system configuration diagram of an operating force measurement device according to a first embodiment of the present invention. The figure which shows the recombination state of the operating force measuring device which concerns on 1st embodiment of this invention, (a) The schematic diagram which shows the 1st aspect for measuring the operating force at the time of door opening, (b) When a door is closed The schematic diagram which shows the 2nd aspect for measuring the operating force of. The figure which shows the recombination state of the operating force measuring device which concerns on 1st embodiment of this invention, (a) The perspective schematic diagram which shows the 1st aspect for measuring the operating force at the time of door opening, (b) Door closing The perspective schematic diagram which shows the 2nd aspect for measuring the operation force at the time. The schematic diagram which shows the relationship between the door and the door handle at the time of door opening and closing when the angle (theta) of a door handle is considered. The system block diagram of the operating force measuring apparatus which concerns on 2nd embodiment of this invention. The figure which shows the recombination state of the operating force measuring apparatus which concerns on 2nd embodiment of this invention, (a) The perspective schematic diagram which shows the 1st aspect for measuring the operating force at the time of door opening, (b) Door closing The perspective schematic diagram which shows the 2nd aspect for measuring the operation force at the time.

Next, embodiments of the invention will be described.
First, the overall configuration of the automotive door handle operating force measuring apparatus according to the first embodiment of the present invention will be described with reference to FIGS.
In the following description, as shown in FIGS. 1 and 2, a three-dimensional coordinate system (hereinafter referred to as an XYZ coordinate system) based on the door 2a provided in the vehicle 2 is defined.
In the XYZ coordinate system, the length direction of the door 2a is defined as the X-axis direction, the thickness direction is defined as the Y-axis direction, and the height direction is defined as the Z-axis direction, and the operating force F in the XYZ coordinate system in the X-axis direction is defined. The component force is defined as Fx, the component force in the Y-axis direction is defined as Fy, and the component force in the Z-axis direction is defined as Fz.
And as shown in FIG. 2, the opening degree (angle) of the door 2a in the vehicle 2 is prescribed | regulated as (phi).

  As shown in FIG. 1, the operating force measuring device 1 according to the first embodiment of the present invention is a device for measuring the operating force acting on the door handle 2b when a person opens and closes the door 2a in the vehicle 2. Yes, it is composed of a measurement handle 3, a door angle measuring device 4, a computing unit 5, and the like.

  The measurement handle 3 is a part for constituting an operation unit that is operated by a person instead of the door handle 2b in the measurement of the operation force by the operation force measuring apparatus 1, and is attached to the door handle 2b as shown in FIG. As shown in FIG. 3, the mounting portion 6, the operation portion 7, the load sensors 8, 8 and the like are provided.

The attachment portion 6 is a portion for fixing the measurement handle 3 to the door handle 2b, and includes a clamp portion 6a that is a portion capable of clamping the door handle 2b.
The measurement handle 3 can clamp the door handle 2b with the clamp portion 6a by tightening the screw member constituting the clamp portion 6a, thereby performing processing such as drilling the door handle 2b. Without being configured, the measurement handle 3 can be fixed to the door handle 2b.

The operation unit 7 constitutes a part of the measurement handle 3 that is gripped by a person, and includes a gripping part 7a, a connecting part 7b, and the like.
Then, instead of gripping the door handle 2b in a state where the measurement handle 3 is fixed to the door handle 2b, the operation unit 7 grips the grip 7a of the operation unit 7 so that a person can handle the measurement handle 3 The door 2a can be opened and closed by operating.

The load sensors 8 and 8 are interposed between the connecting portions 7 b and 7 b of the operation portion 7 and the connecting portions 6 b and 6 b of the attachment portion 6.
And the attaching part 6 and the operation part 7 are comprised so that it may be connected via the load sensor 8 * 8 of two (2 in this embodiment).

In other words, when an operation force acting when a person operates the operation unit 7 is transmitted to the attachment unit 6, all the operation force is input to the load sensors 8 and 8.
With this configuration, when a person holds the operation unit 7 to open and close the door 2a, the operation force acting on the door handle 2b via the measurement handle 3 can be detected by the load sensors 8 and 8. It is configured as follows.

The load sensor 8 is a sensor (load cell) that can simultaneously detect stresses in three orthogonal directions, and XYZ coordinates of an operating force that acts on the door handle 2b via the measurement handle 3 by the load sensor 8. The system is configured to be able to detect a component force in each axial direction in the system.
The load sensors 8 and 8 are connected to the computing unit 5, and are configured to calculate the operating force in the XYZ coordinate system by the computing unit 5 based on the measurement values obtained by the load sensors 8 and 8.

  The operating force measuring device 1 employs a piezoelectric load cell with a small drift amount as the load sensor 8, thereby disposing the load sensor 8 in a limited narrow space around the door handle 2 b. This makes it possible to accurately measure the operating force without being affected by drift.

  Further, the measurement handle 3 measures the operating force when the door 2a is opened (that is, the door handle 2b is pulled), as shown in FIGS. 4 (a), 4 (b) and 5 (a), 5 (b). The first embodiment, which is a mode for the above, and the second mode, which is a mode for measuring the operating force when the door 2a is closed (that is, when the door handle 2b is pushed), are used in combination. Has been.

  4 (a) and 5 (a) of the operating force measuring device 1 is an embodiment for measuring the operating force F when the door 2a is opened. By pulling the part 7, the load sensor 8 is configured to be stressed in the compressing direction.

  That is, in the measurement handle 3 according to the first aspect, the connecting portions 6b and 6b on the attachment portion 6 side are arranged at positions farther from the door handle 2b than the connecting portions 7b and 7b on the operation portion 7 side. In addition, the load sensor 8 is interposed between the connecting portion 6b and the connecting portion 7b.

  4B and 5B of the operating force measuring device 1 is an embodiment for measuring the operating force F when the door 2a is closed. By pressing the operation unit 7, a stress in a compressing direction acts on the load sensor 8.

  That is, in the measurement handle 3 according to the second aspect, the connecting portions 6b and 6b on the mounting portion 6 side are disposed closer to the door handle 2b than the connecting portions 7b and 7b on the operating portion 7 side. The load sensor 8 is interposed between the connecting portion 6b and the connecting portion 7b.

As described above, the measurement handle 3 can be changed to a first mode used when the door 2a is opened and a second mode used when the door 2a is closed. The measuring handle 3 in the operating force measuring device 1 can be realized with a simple configuration using only a small number of small load sensors (two in this embodiment).
Further, by using the measurement handle 3 having such a configuration, both the opening and closing operation force of the door 2a can be detected while using the simple load sensor 8 that can detect only the force in the compression direction. It becomes possible to cope with the measurement.

The door angle measuring device 4 is configured by using a so-called rotary encoder, and is arranged at a hinge portion (not shown) of the door 2a as shown in FIG. It is configured to detect.
The door angle measuring device 4 is connected to the calculator 5, and the angle φ of the door 2 a measured by the door angle measuring device 4 is input to the calculator 5.

The computing unit 5 is configured by, for example, a combination of a dedicated amplifier attached to the load sensor 8 and a general-purpose personal computer in which a predetermined computation program is installed.
The computing unit 5 is configured to calculate the operation force F for the door handle 2b in the XYZ coordinate system based on the measured value by the load sensors 8 and 8 and the measured value of the angle 2 of the door 2a by the door angle measuring unit 4. Yes.

Next, the measurement state of the operating force with respect to the door handle for automobiles by the operating force measuring device 1 according to the first embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 3, in the measurement of the operating force F by the operating force measuring device 1, the measured values F ₁ and F ₂ by the load sensors 8 and 8 provided in the measuring handle 3 are input to the amplifier of the arithmetic unit 5. Is done.

A total of six raw measurement values (F _x1 , F _y1 , F _z1 , F _x2 , F _y2 , F _z2 ) are output from the amplifier as a component force in each axial direction of the XYZ coordinate system. From the six outputs, the computing unit 5 obtains output values F ′ (F _x ′, F _y ′, F _z ′) as shown in FIG.
The output value F ′ (F _x ′, F _y ′, F _z ′) is calculated by the following formula 1.

  Next, in the calculator 5, the obtained output value F ′ and the angle φ of the door 2 a input from the door angle measuring device 4 are converted into determinants for polarity conversion (shown below) as shown in FIG. 3. Substitute into equation 2).

In the determinant shown in Equation 2, the value of the constant LR in the determinant is selected according to the direction of the door 2a to which the measurement handle 3 is attached, and the constant OC in the determinant is determined according to the opening / closing direction of the door 2a. Select a value.
For example, the value of the constant LR in the determinant is selected as “1” when the measurement handle 3 is attached to the right door 2a of the vehicle, and the measurement handle 3 is attached to the left door 2a of the vehicle. "-1" is selected when it is set.
The value of the constant OC in the determinant is selected as “1” when the door 2a is opened and “−1” is selected when the door 2a is closed.

Then, the operation force F (F _x , F _y , F _z ) in the XYZ coordinate system is obtained from the result of substitution into the determinant expressed by Formula 2.

As described above, according to the operating force measuring apparatus 1 according to the first embodiment of the present invention, the operation of the door handle 2b can be performed without being affected by the gripping force of a person while using the small load sensors 8 and 8. The operating force F (F _x , F _y , F _z ) in the XYZ coordinate system necessary for evaluating the feeling can be obtained with high accuracy.

In the present embodiment, the operating force measuring device is applied to the door handle 2b that opens and closes the door 2a by pulling the door handle 2b in a substantially horizontal direction when the rotation axis direction of the door handle 2b is substantially vertical. 1 is illustrated, but the application target of the operating force measurement device according to the present invention is not limited to such a door handle.
That is, for example, the operating force measuring device according to the present invention is applied to a door handle in which the door handle is pivoted in a substantially horizontal direction and the door is opened by lifting the door handle upward. Can be applied.

That is, the operating force measuring apparatus 1 according to the first embodiment of the present invention is attached to the door handle 2b of the door 2a of the vehicle 2 and constitutes a part for inputting the operating force F to the door handle 2b. A measuring handle 3, a door angle measuring device 4 for detecting the rotation angle of the door 2a, and a computing unit 5 for calculating an operating force F input to the door handle 2b via the measuring handle 3. The handle 3 includes an attachment portion 6 that is a portion for fixing the measurement handle 3 to the door handle 2b, an operation portion 7 that is a portion for a person to input the operation force F, and the attachment portion 6 And a plurality of (two in the present embodiment) load sensors 8 and 8 interposed in the operation unit 7 at a portion where the operation unit 7 is connected. 4 and a plurality of load sensors 8, 8 Based on the measured value, and calculates the operating force F which is input to the door handle 2b via a measuring wheel 3.
With such a configuration, while using the small load sensors 8 and 8, the input of a moment can be allowed, the influence of a person's gripping force and the like can be eliminated, and the operating force F acting on the door handle 2b is accurately measured. be able to.

Moreover, in each operating force measuring device 1 according to the first embodiment of the present invention, the measurement handle 3 is a first mode for detecting the operating force F acting on the door handle 2b when the door 2a is closed. And the 2nd aspect for detecting the operation force F which acts on the door handle 2b when opening the door 2a is comprised so that a change is possible.
With such a configuration, the measurement handle 3 can be configured using a general-purpose load sensor 8.
Thereby, an inexpensive operation force measuring device 1 can be realized with a simple configuration.

Next, the entire configuration of the operating force measuring apparatus for an automobile door handle according to the second embodiment of the present invention will be described with reference to FIGS.
In the following description, in addition to the XYZ coordinate system based on the direction of the door 2a, a three-dimensional coordinate system (hereinafter referred to as a PQR coordinate system) based on the direction of the door handle 2b shown in FIG. doing.
Then, as shown in FIG. 6, the length direction of the door handle 2b is defined as the P-axis direction, the thickness direction is defined as the Q-axis direction, and the height direction is defined as the R-axis direction, and the operation force F _s in the PQR coordinate system is defined. The component force in the P-axis direction is _defined as F _p , the component force in the Q-axis direction is defined as F _q , and the component force in the R-axis direction is defined as F _r .
As shown in FIG. 6, the opening degree (angle) of the door 2a in the vehicle 2 is defined as φ, and the angle of the door handle 2b with respect to the door 2a is defined as θ.

The operating force F to be measured by the operating force measuring device 11 is a force in the XYZ coordinate system with the direction of the door 2a as a reference.
However, the force may be measured directly by the operating force measuring device 11, since an operation force F _s in the PQR coordinate system with reference to the direction of the door handle 2b, the operating force measuring device 1, the operation in the PQR coordinate system The force F _s is converted into a force in an XYZ coordinate system based on the direction of the door 2a to obtain the operation force F.

  Similar to the operation force measurement device 1, the operation force measurement device 11 according to the second embodiment of the present invention measures the operation force F acting on the door handle 2b when a person opens and closes the door 2a in the vehicle 2. As shown in FIG. 7, the apparatus includes a measurement handle 13, a door angle measuring device 14, a computing unit 15, and the like.

  The measurement handle 13 is a part for constituting an operation unit operated by a person instead of the door handle 2b in measurement of the operation force by the operation force measuring device 11, and is used in a state of being attached to the door handle 2b. It is set as the structure provided with the attaching part 6, the operation part 7, load sensor 8,8 grade | etc.,.

The attachment portion 6 is a portion for fixing the measurement handle 13 to the door handle 2b, and includes a clamp portion 6a that is a portion capable of clamping the door handle 2b.
The measurement handle 13 can clamp the door handle 2b with the clamp portion 6a by tightening the screw member constituting the clamp portion 6a, thereby performing processing such as drilling the door handle 2b. Without being configured, the measurement handle 13 can be fixed to the door handle 2b.

The operation unit 7 constitutes a part of the measurement handle 13 that is gripped by a person, and includes a gripping unit 7a, a connecting unit 7b, and the like.
Then, instead of gripping the door handle 2b in a state where the measurement handle 13 is fixed to the door handle 2b, the operation unit 7 grips the grip 7a of the operation unit 7 so that a person can measure the measurement handle 13. The door 2a can be opened and closed by operating.

The load sensors 8 and 8 are interposed between the connecting portions 7 b and 7 b of the operation portion 7 and the connecting portions 6 b and 6 b of the attachment portion 6.
And the attaching part 6 and the operation part 7 are comprised so that it may be connected via the load sensor 8 * 8 of two (2 in this embodiment).

In other words, when an operation force acting when a person operates the operation unit 7 is transmitted to the attachment unit 6, all the operation force is input to the load sensors 8 and 8.
With such a configuration, when a person holds the operation unit 7 to open and close the door 2a, the operation force acting on the door handle 2b via the measurement handle 13 can be detected by the load sensors 8 and 8. It is configured as follows.

The load sensor 8 is a sensor (load cell) that can simultaneously detect stresses in three orthogonal directions, and the PQR coordinates of the operating force acting on the door handle 2b via the measurement handle 3 by the load sensor 8. The system is configured to be able to detect a component force in each axial direction in the system.
In addition, each load sensor 8, 8 is connected to a computing unit 15, which will be described later, and based on the measured value of the operating force (component force in each axial direction) in the PQR coordinate system by each load sensor 8, 8. The calculator 15 is configured to calculate the operating force in the XYZ coordinate system.

  Further, as shown in FIGS. 8A and 8B, the operating force measuring device 11 according to the second embodiment of the present invention closes the door 2a when measuring the operating force F when the door 2a is opened. When the operating force F is measured, the configuration of the apparatus is changed.

  The first mode shown in FIG. 8A of the operating force measuring device 11 is a mode for measuring the operating force F when the door 2a is opened. By pulling the operating unit 7 on the measuring handle 13, the operating mode F is measured. The load sensor 8 is configured to be subjected to a stress in the compressing direction.

  That is, in the measurement handle 13 of the first aspect, the connecting portions 6b and 6b on the attachment portion 6 side are arranged at positions that are further away from the door handle 2b than the connecting portions 7b and 7b on the operation portion 7 side. In addition, the load sensor 8 is interposed between the connecting portion 6b and the connecting portion 7b.

  Further, the second mode shown in FIG. 8B of the operating force measuring device 11 is a mode for measuring the operating force F when the door 2a is closed. In the measuring handle 13, the operating unit 7 is pushed. Accordingly, the load sensor 8 is configured to be subjected to a stress in a compressing direction.

  That is, in the measurement handle 13 according to the second aspect, the connecting portions 6b and 6b on the attachment portion 6 side are disposed closer to the door handle 2b than the connecting portions 7b and 7b on the operation portion 7 side. The load sensor 8 is interposed between the connecting portion 6b and the connecting portion 7b.

  In addition, the operating force measuring device 11 includes a door handle displacement measuring device 9 that is a device for detecting the displacement of the door handle 2b relative to the door 2a in the measurement handle 13, and in this respect, the first This is different from the operating force measuring apparatus 1 according to the embodiment.

  Further, the operating force measuring device 11 employs a different calculation algorithm in the computing unit 15 than the computing unit 5 of the operating force measuring device 1. Also in this respect, the operating force measuring device according to the first embodiment. 1 and different.

  And the structure of the door angle measuring device 14 in the operating force measuring apparatus 11 and the structure in another part can be made into the structure common in the structure in the operating force measuring apparatus 1 which concerns on 1st embodiment.

The door handle displacement measuring device 9 is a device for detecting a separation distance L of the door handle 2b with respect to the door 2a.
And in the operation force measuring device 11, based on the separation distance L detected by the door handle displacement measuring device 9, the calculator 5 calculates the angle θ of the door handle 2b with respect to the door 2a.

  In the present embodiment, the case where the door handle displacement measuring device 9 is used to detect the angle θ of the door handle 2b with respect to the door 2a is illustrated, but the angle θ of the door handle 2b with respect to the door 2a is illustrated. It is good also as a structure which arrange | positions directly the angle sensor to detect in the rotation base part of the door handle 2b with respect to the door 2a.

Next, the measurement state of the operating force F with respect to the door handle 2b by the operating force measuring device 11 according to the second embodiment of the present invention will be described with reference to FIG.
In the operating force measuring apparatus 1 according to the first embodiment of the present invention, the axial directions in the PQR coordinate system and the axial directions in the XYZ coordinate system coincide with each other without considering the angle θ of the door handle 2b with respect to the door 2a. It is assumed that the operating force F is calculated.

  However, when the door handle 2b is operated to open and close the door 2a, the angle θ of the door handle 2b with respect to the door 2a actually changes. By considering the above, it becomes possible to measure the operating force F with higher accuracy.

  Therefore, the operating force measurement device 11 according to the second embodiment of the present invention employs an algorithm that considers the angle θ in the calculation process of the operating force F by the computing unit 15.

As shown in FIG. 7, in the measurement of the operating force F by the operating force measuring device 11, measured values F _s1 and F _s2 by the load sensors 8 and 8 provided in the measuring handle 3 are input to the amplifier.

Then, a total of six raw measurement values (F _p1 , F _q1 , F _r1 , F _p2 , F _q2 , F _r2 ) are output from the amplifier as component forces in the direction of each axis of the PQR coordinate system, From the outputs of these six systems, the calculator 15 obtains output values F _s (F _sp , F _sq , F _sr ) as shown in FIG.
The output value F _s (F _sp , F _sq , F _sr ) is calculated by Equation 3 shown below.

Next, as shown in FIG. 7, the computing unit 15 corrects the output value F _s based on the angle θ of the door handle 2b, and outputs the corrected output values F _s ′ (F _sp ′, F _sq ′, F _sr ') is calculated.
The corrected output value F _s ′ (F _sp ′, F _sq ′, F _sr ′) is calculated by the following formula 4.

  Further, the angle θ of the door handle 2b can be calculated by the following formula 5 based on the displacement amount of the door handle 2b (separation distance L with respect to the door 2a) and the rotation radius r of the door handle 2b. .

Next, the computing unit 15 uses the obtained corrected output value F _s ′ and the angle φ of the door 2a input from the door angle measuring device 4 as a determinant for polarity conversion as shown in FIG. Substitute into (Equation 6 below).

In the determinant expressed by Equation 6, the value of the constant LR in the determinant is selected according to the direction of the door 2a to which the measurement handle 3 is attached, and the constant OC in the determinant is determined according to the opening / closing direction of the door 2a. Select a value.
For example, the value of the constant LR in the determinant is selected as “1” when the measurement handle 3 is attached to the right door 2a of the vehicle, and the measurement handle 3 is attached to the left door 2a of the vehicle. "-1" is selected when it is set.
The value of the constant OC in the determinant is selected as “1” when the door 2a is opened and “−1” is selected when the door 2a is closed.

Then, the operation force F (F _x , F _y , F _z ) in the XYZ coordinate system is obtained from the result of substitution into the determinant expressed by Equation 5.

As described above, in the operation force measuring device 11 according to the second embodiment of the present invention, the operation feeling of the door handle 2b is obtained by considering the angle θ of the door handle 2b with respect to the door 2a in the calculation of the operation force F. The operating force F (F _x , F _y , F _z ) in the XYZ coordinate system necessary for the evaluation can be determined more accurately than the operating force measuring device 1.

That is, the operating force measuring device 11 according to the second embodiment of the present invention further includes a door handle displacement measuring device 9 that detects a displacement (that is, a separation distance L) of the door handle 2b with respect to the door 2a. The device 5 corrects the measured values of the load sensors 8 and 8 based on the measured values of the door handle displacement measuring device 9.
With such a configuration, the operating force F acting on the door handle 2b can be measured with higher accuracy.

1 Operating force measuring device (first embodiment)
DESCRIPTION OF SYMBOLS 2 Vehicle 2a Door 2b Door handle 3 Measuring handle 4 Door angle measuring device 5 Calculator 6 Operation part 7 Mounting part 8 Load sensor 9 Door handle displacement measuring device 11 Operating force measuring device (2nd embodiment)
13 Measuring Handle 14 Door Angle Measuring Device 15 Calculator

Claims (3)

A measurement handle that is attached to a door handle of a vehicle door and constitutes a part for inputting an operation force to the door handle;
A door angle measuring device for detecting a rotation angle of the door;
A calculator for calculating the operating force input to the door handle via the measurement handle;
With
The measuring handle is
An attachment portion which is a part for fixing the measurement handle to the door handle;
An operation unit which is a part for a person to input an operation force;
A plurality of load sensors interposed between the attachment portion and the operation portion in a portion connecting the attachment portion and the operation portion;
With
By the computing unit ,
Based on the measured values of the plurality of load sensors,
Calculating the operating force at the rotation angle measured by the door angle measuring device ;
An operating force measuring device for a vehicle door handle. A door handle displacement amount measuring device for detecting a displacement amount of the door handle with respect to the door;
By the computing unit,
Based on the measured value of the door handle displacement measuring device,
Correcting measured values of the plurality of load sensors;
The operating force measuring apparatus for a vehicle door handle according to claim 1. The measuring handle is
A first mode for detecting an operating force acting on the door handle when the door is closed;
A second mode for detecting an operating force acting on the door handle when the door is opened;
Configured to be changeable,
The operating force measuring device for a vehicle door handle according to claim 1 or 2.

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