JP2008175564A - Running test system of motorcycle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a running test system capable of diversifying test items on a running performance or the like. <P>SOLUTION: The running test system 1 includes a running test board 4 for running simulatingly a motorcycle 100 which is a test object, a support mechanism 2 and a support mechanism 5 for supporting the motorcycle 100, a speed sensor 45 for detecting simulative running speed of the motorcycle 100, and a control device 10 for controlling the support mechanism 2 and the support mechanism 5. The support mechanism 2 and the support mechanism 5 are constituted so that support of the motorcycle 100 can be released, and the control device 10 releases support of the motorcycle 100 by the support mechanism 2 and the support mechanism 5 corresponding to the running speed detected by the speed sensor 45. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a running test system for running a motorcycle to be tested in a simulated manner on a test platform and testing its running performance and the like.

Conventionally, a running test system that tests the running performance, durability, etc. of a motorcycle on a running test stand such as a chassis dynamometer while suppressing the movement of the motorcycle to be tested while moving back and forth. Is being used. For example, Patent Document 1 discloses a running test system that includes a doll simulating the outer shape of a human body placed on a motorcycle to be tested, and a throttle operating device that is mounted on the doll and operates a throttle of the motorcycle. Has been proposed. In such a conventional traveling test system, a support mechanism that supports the vehicle body from the side is used in order to prevent the vehicle body from falling during the traveling test.
JP 2001-281107 A

  However, the conventional running test system has a problem that the test items for running performance and the like are limited because the vehicle body is always supported by the support mechanism during the running test. For example, it has been difficult to test the steering force required for steering operation.

  The present invention has been made in view of the above-mentioned problems, and its purpose is to test items in a running test system for running a motorcycle on a running test stand in a simulated manner and testing its running performance and the like. It is to provide a running test system that can diversify.

  In order to solve the above-described problems, a running test system according to the present invention includes a running test stand that simulates running a motorcycle to be tested, and a support for supporting a motorcycle that is driven on the running test stand. A mechanism, speed detecting means for detecting a simulated running speed of the motorcycle on the running test table, and control means for controlling the support mechanism. The support mechanism is configured to be able to release the support of the motorcycle, and the control means releases the support of the motorcycle by the support mechanism according to a traveling speed detected by the speed detection means. .

  According to the present invention, it is possible to release the support of the motorcycle by the support mechanism, and it is possible to diversify the test items for running performance and the like.

  In one aspect of the present invention, a control device that is provided on the motorcycle and controls the motorcycle may be further provided. According to this aspect, it is possible to further diversify the test items regarding the running performance and the like. In addition, when a tester steers a motorcycle to be tested, variations in test results are likely to occur. However, according to this aspect, variations in such test results are reduced.

  In this aspect, the support mechanism supports the motorcycle on the running test table by supporting the steering device provided on the motorcycle, and the running test system includes: You may further provide the load detection means which detects the load concerning the said support mechanism. Based on the load detected by the load detection means, the behavior of the motorcycle after releasing the support of the motorcycle by the support mechanism can be estimated. In addition, since the support mechanism supports the control device provided on the motorcycle, the stability of the posture of the occupant during actual traveling of the motorcycle can be estimated.

  In this aspect, the behavior detection means for detecting the behavior of the motorcycle and the behavior of the motorcycle detected by the behavior detection means in a state where the support of the motorcycle by the support mechanism is released. You may further provide the measurement means to measure. In this case, the behavior detection means may be provided in the control device. This makes it possible to estimate the behavior of the motorcycle felt by the passenger during actual traveling of the motorcycle. The behavior detecting means may include a handle load detecting means for detecting a load applied to the handle of the motorcycle. As a result, it is possible to estimate the steering operation load felt by the passenger during actual traveling of the motorcycle. Further, the behavior detecting means may include a handle rotation angle detecting means for detecting a rotation angle of the handle of the motorcycle. This makes it possible to estimate the steering wheel behavior (for example, steering wheel shake) felt by the passenger during actual traveling of the motorcycle.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram of a traveling test system 1 that is an example of an embodiment of the present invention. FIG. 1 shows a state in which a motorcycle 100 to be tested is viewed from the side. FIG. 2 is a diagram showing a state in which the control robot 3 placed on the motorcycle 100 is viewed from above. FIG. 3 is a schematic plan view of the support mechanism 2 included in the traveling test system 1, and FIG. 4 is a schematic plan view of the support mechanism 5. 1 and 2, the motorcycle 100 to be tested is indicated by a two-dot chain line.

  As shown in FIG. 1, the travel test system 1 includes a support mechanism 2, a support mechanism 5, a control robot 3, a travel test table 4, and a control device 10.

  The travel test table 4 is, for example, a chassis dynamometer, and automatically rotates by rotating the rear wheel 101 and the front wheel 102 while suppressing relative movement of the motorcycle 100 to be tested with respect to the travel test table 4. The motorcycle 100 is run in a simulated manner. The travel test table 4 includes front wheel rollers 41a and 41b, rear wheel rollers 42a and 42b, and a speed sensor 45.

  Each roller is arranged such that a part of its outer peripheral surface is exposed from the upper surface portion 4 a of the traveling test table 4. The rear wheel rollers 42 a and 42 b are arranged so that the outer peripheral surfaces thereof are in contact with the rear wheel 101 of the motorcycle 100. Further, the front wheel rollers 41a and 41b are arranged at intervals in the front-rear direction (the direction indicated by A in FIG. 1), and a belt 43 is wound around these rollers. The front wheel 102 of the motorcycle 100 is disposed on the upper surface of the belt 43. The front wheel rollers 41a and 41b and the rear wheel rollers 42a and 42b rotate at a speed corresponding to the rotational speeds of the front wheels 102 and the rear wheels 101, so that the motorcycle 100 is relative to the traveling test table 4. Movement is suppressed.

  In the example described here, a steering robot 3 described later controls the motorcycle 100 to rotate the rear wheel 101, and the rear wheel rollers 42a and 42b rotate in accordance with the rotation. Further, the front wheel rollers 41a and 41b are interlocked with the rotation of the rear wheel rollers 42a and 42b so as to rotate the front wheel 102 at a speed equal to that of the rear wheel 101.

  The speed sensor 45 is, for example, a rotary encoder, and here outputs an electrical signal corresponding to the rotational speed of the rear wheel roller 42 b to the control device 10. The control device 10 detects a simulated traveling speed (hereinafter simply referred to as a traveling speed) of the motorcycle 100 on the traveling test stand 4 based on the electric signal.

  The support mechanism 2 and the support mechanism 5 will be described. In the example described here, the support mechanism 2 holds the front wheel 102 of the motorcycle 100, and the support mechanism 5 holds the rear wheel 101. Thus, the motorcycle 100 is supported in an upright state without falling down. First, the support mechanism 2 will be described.

  As shown in FIG. 3, the support mechanism 2 includes a pair of support rods 21 and 22, support rod drive units 23 and 24, and support load detection units 25 and 26.

  The support rods 21 and 22 are arranged such that the longitudinal direction thereof is in the vehicle width direction (the direction indicated by B in FIG. 3). The end portions 21a and 22a face each other with a gap provided therebetween. During the running test of the motorcycle 100, the front wheel 102 is disposed in the gap. The end portions 21a and 22a support the interlocking rollers 21c and 22c in a rotatable manner. The interlocking rollers 21c and 22c are interlocked with the rotation of the front wheel 102 when abutting against the rotating front wheel 102 during the running test.

  The support rod drive units 23 and 24 include, for example, an actuator, a drive circuit of the actuator (a circuit that supplies a drive current to the actuator based on an instruction from the control device), and air that allows slight displacement of the support rods 21 and 22. Includes cylinders. Here, the support rod driving units 23 and 24 are installed at the bases of the support rods 21 and 22. The support rod drive units 23 and 24 are driven in accordance with a signal input from the control device 10, and the distance between the end portions 21 a and 22 a of the support rods 21 and 22 is narrowed (direction indicated by F <b> 1 in FIG. 3) or widens. The support rods 21 and 22 are moved in the direction (the direction indicated by F2 in FIG. 3). As a result, the support rods 21 and 22 support the front wheel 102 from the vehicle width direction or release the support.

  In addition, the support rod drive parts 23 and 24 are supported by being accommodated in the housing | casing 28 and 29 arrange | positioned so that the one part may mutually face. Rollers 27 are stretched around the casings 28 and 29. The roller 27 is installed so as to be positioned in front of the front wheel 102, and both end portions 27 a and 27 b are rotatably supported by the casings 28 and 29. When the roller 27 comes into contact with the rotating front wheel 102 during the running test, the roller 27 is interlocked with the rotation of the front wheel 102. This prevents the motorcycle 100 from jumping forward during the running test.

  The support load detection units 25 and 26 include, for example, a strain sensor and a pressure sensor, detect the load applied to the support rods 21 and 22 from the front wheel 102 during the running test, and control the electrical signal corresponding to the load. 10 is output. In the example described here, the support load detection units 25 and 26 are attached to the middle portions of the support rods 21 and 22 to detect distortion generated in the support rods 21 and 22 and pressure in the longitudinal direction of the support rods 21 and 22. is doing.

  The support load detection units 25 and 26 may include pressure sensors that detect air pressure, and the pressure sensors may be attached to the air cylinders of the support rod drive units 23 and 24. Then, an electrical signal corresponding to the air pressure in the cylinder may be output to the control device 10.

  Next, the support mechanism 5 will be described. The support mechanism 5 is generally the same as the support mechanism 2, and includes a pair of support rods 51 and 52 and support rod driving units 53 and 54.

  The end portions 51a, 52a of the support rods 51, 52 face each other with a gap provided therebetween, and the rear wheel 101 is disposed in the gap. The end portions 51a and 52a rotatably support the interlocking rollers 51c and 52c interlocked with the rotation of the rear wheel 101 when the end portions 51a and 52a come into contact with the rear wheel 101 rotating during the running test.

  Like the support rod drive units 23 and 24, the support rod drive units 53 and 54 include, for example, an actuator, a drive circuit for the actuator, an air cylinder that allows slight displacement of the support rods 51 and 52, and the like. . The support rod driving units 53 and 54 are also driven in accordance with a signal input from the control device 10, and the distance between the end portions 51a and 52b of the support rods 51 and 52 is narrowed (direction indicated by F1 in FIG. 4) or widens. The support rods 51 and 52 are moved in the direction (the direction indicated by F2 in FIG. 4).

  The support rod driving units 53 and 54 are supported by being accommodated in the casings 58 and 59. Rollers 57 installed so as to be positioned behind the rear wheels 101 are hung on the casings 58 and 59. The roller 57 is rotatably supported by the casings 58 and 59. The roller 57 prevents the motorcycle 100 from jumping backward during the running test.

  As shown in FIGS. 1 and 2, the control robot 3 includes a torso 31, a pair of left and right legs 32, 32, a throttle operation mechanism 33, a clutch lever operation mechanism 34, and a change pedal operation mechanism 35. I have. In the example described here, handle load detection units 36 and 37 are attached to the control robot 3.

  As shown in FIG. 2, the throttle operation mechanism 33 includes a throttle drive unit 33a and an arm 33b. The tip of the arm 33b is attached to the throttle 103 of the motorcycle 100, and the throttle 103 is rotated by the operation of the throttle driving unit 33a.

  In the example described here, an attachment member 33 c that holds the throttle 103 is attached to the throttle 103. The distal end portion of the arm 33b is radially separated from the rotation shaft of the throttle 103, and is attached to the throttle 103 via an attachment member 33c.

  The throttle drive unit 33 a includes an actuator, a drive circuit that supplies a drive current to the actuator in accordance with a control signal input from the control device 10, and is driven according to the control signal of the control device 10. A base portion of the arm 33b is attached to the output shaft via a connecting member 33d extending in a radial direction from an output shaft of an actuator provided in the throttle drive portion 33a. When the actuator of the throttle drive unit 33a rotates in one direction, the arm 33b is pulled and the throttle 103 rotates from the initial rotation position to the near side. On the other hand, when the actuator rotates in the opposite direction, the arm 33b is pressed to rotate the throttle 103 to the initial rotation position.

  The throttle drive 33a is attached to the end of the arm 33e. A base portion of the arm 33e is connected to and supported by a rod 39 extending forward from the body portion 31 via a support member 33f.

  The clutch lever operation mechanism 34 includes a clutch lever drive unit 34a and an arm 34b. The tip of the arm 34 b is attached to the clutch lever 104 of the motorcycle 100.

  The clutch lever drive unit 34a includes an actuator and a drive circuit that supplies a drive current to the actuator according to a control signal input from the control device 10, and is driven according to the control signal. The base part of the arm 34b is attached to the clutch lever driving part 34a, and moves to the near side (direction shown by C in FIGS. 1 and 2) by driving the clutch lever driving part 34a. As a result, the arm 34b pulls the clutch lever 104 to the near side (grip 109 side). The clutch lever drive unit 34a is also driven according to a signal input from the control device 10 as will be described later.

  The clutch lever drive 34a is attached to the end of the arm 34e. The base portion of the arm 34 e is connected to the rod 39 via the support member 34 f and supported by the rod 39.

  The body portion 31 is placed on the seat of the motorcycle 100 to be tested during a running test. The body portion 31 includes, for example, a battery that supplies a drive current to a throttle drive unit 33a, a clutch lever drive unit 34a, and a change pedal drive unit 35a described later.

  As shown in FIG. 1, the leg portions 32, 32 are attached to the trunk portion 31. The distal end portion of the leg portion 32 is attached to the step 105 of the motorcycle 100. The leg portion 32 has a shape imitating a human foot, and includes a thigh portion 32a and a shin portion 32b.

  The change pedal operation mechanism 35 is attached to the left shin portion 32b. The change pedal operation mechanism 35 includes a change pedal drive unit 35a and an arm 35b. The tip of the arm 35b is attached to the change pedal 106. The base part of the arm 35b is connected to the change pedal drive part 35a.

  The change pedal drive unit 35a includes an actuator and a drive circuit that supplies a drive current to the actuator according to a control signal input from the control device 10, and is driven according to the control signal. The base portion of the arm 35b moves in the vertical direction (direction indicated by D in FIG. 1) by driving the actuator of the change pedal drive portion 35a. As a result, the change pedal 106 is pressed downward or pulled upward by the arm 35b.

  The handle load detection units 36 and 37 include, for example, a strain sensor and a pressure sensor, and detect a rotational load applied to the handle 107 of the motorcycle 100. In the example described here, as shown in FIG. 2, the handle load detection unit 36 is attached to the middle part of the arm 33 e, and outputs an electrical signal corresponding to the load applied to the arm 33 e by the rotational force applied to the handle 107. Output to the control device 10. The handle load detection unit 37 is attached to the middle part of the arm 34e, and outputs an electrical signal corresponding to the load applied to the arm 34e by the rotational force applied to the handle 107 to the control device 10.

  In the example described here, the motorcycle 100 to be tested is described as a motorcycle having a manual transmission. However, the motorcycle to be tested may have a continuously variable transmission. Good. In this case, the control robot 3 may include only the throttle operation mechanism 33 without including the clutch lever operation mechanism 34 and the change pedal operation mechanism 35.

  Here, the configuration of the control device 10 will be described. FIG. 5 is a block diagram illustrating a configuration of the control device 10. As shown in the figure, the control device 10 includes a control unit 11, a storage unit 12, an interface unit 13, an input unit 14, and a display unit 15.

  The control unit 11 includes a CPU (Central Processing Unit), controls the traveling test system 1 according to a program stored in the storage unit 12, acquires measurement data measured by the traveling test, and displays the display unit 15. Or stored in the storage unit 12. The contents of the process executed by the control unit 11 will be described later in detail.

  The storage unit 12 includes a volatile memory and a nonvolatile memory, and holds a program executed by the control unit 11. Moreover, the measurement data acquired by the running test are held.

  The input unit 14 includes, for example, operation buttons and a keyboard, and outputs a signal based on the operation of the test worker to the control unit 11. In the example described here, a signal indicating a running test condition (for example, the running speed of the motorcycle 100 as the test condition) is output to the control unit 11 in accordance with the operation of the test operator.

  The display unit 15 includes, for example, a display, and displays measurement data acquired during the running test according to a signal input from the control unit 11.

  The interface unit 13 includes, for example, a digital / analog conversion circuit, an analog / digital conversion circuit, and the like. The interface unit 13 converts analog signals input from the support load detection units 25 and 26 and the handle load detection units 36 and 37 into digital signals and outputs the digital signals to the control unit 11. In addition, the interface unit 13 receives digital signals (in this case, a throttle drive unit 33a, a clutch lever drive unit 34a, a change pedal drive unit 35a, and support rod drive units 23, 24, 53, and 54) from the control unit 11. A control signal for control) is converted into an analog signal and output to the throttle drive unit 33a, the clutch lever drive unit 34a, the change pedal drive unit 35a, and the support rod drive units 23, 24, 53, and 54.

  Note that the interface unit 13 includes, for example, support load detection units 25 and 26, handle load detection units 36 and 37, a throttle drive unit 33a, a clutch lever drive unit 34a, a change pedal drive unit 35a, and a support via lead wires. It is connected to the rod drive units 23, 24, 53, 54 and the like. The interface unit 13 includes a wireless communication circuit, and after converting and amplifying a digital control signal input from the control unit 11 into an analog control signal, the throttle drive unit 33a, the clutch lever drive unit 34a, the change pedal You may transmit to the drive part 35a and the support rod drive part 23,24,53,54. The interface unit 13 amplifies the analog signals received from the support load detection units 25 and 26 and the handle load detection units 36 and 37 and converts them into digital signals, and then outputs the digital signals to the control unit 11. May be.

  Here, the process executed by the control unit 11 will be described in detail. FIG. 6 is a functional block diagram showing the contents of processing executed by the control unit 11. The control unit 11 includes a control robot control unit 11a, a support mechanism control unit 11d, a vehicle behavior monitoring unit 11e, and a measurement processing unit 11f.

  The control robot control unit 11a controls the throttle drive unit 33a, the clutch lever drive unit 34a, and the change pedal drive unit 35a of the control robot 3 so that the driving state of the motorcycle 100 corresponds to the travel test condition. Specifically, the throttle drive unit 33a, the clutch lever drive unit 34a, and the change pedal drive unit 35a are driven in a preset order to increase or decrease the speed of the motorcycle 100. To do. Further, when the driving state corresponds to the driving test condition, a process for maintaining the driving state is executed.

  The control robot control unit 11a includes an acceleration processing unit 11b and a deceleration processing unit 11c.

  The acceleration processing unit 11b switches the throttle driving unit 33a, the clutch lever driving unit 34a, and the change pedal driving unit 35a when the later-described support mechanism control unit 11d or the measurement processing unit 11f determines that the motorcycle 100 should be accelerated. The driving speed of the motorcycle 100 is increased by driving in a preset order.

  For example, the acceleration processing unit 11b outputs a signal instructing to rotate the throttle 103 by a predetermined angle to the throttle driving unit 33a. As a result, the arm 33b is pulled by the throttle drive unit 33a, the throttle 103 rotates by a predetermined angle, and the throttle opening increases, whereby the motorcycle 100 is accelerated.

  Further, the acceleration processing unit 11b may accelerate the motorcycle 100 by shifting the gear of the transmission of the motorcycle 100. The process in this case is executed as follows, for example. A sensor for detecting the engine speed is installed in advance in the engine of the motorcycle 100. Then, when the engine speed reaches a predetermined speed, the acceleration processing section 11b drives the throttle drive section 33a so that the rotation angle of the throttle 103 returns to the initial angle, and the arm 34b pulls the clutch lever 104. In this manner, the clutch lever driving unit 34a is driven to disengage the clutch. Then, the acceleration processing unit 11b drives the change pedal driving unit 35a so that the arm 35b pulls the change pedal 106 upward once or a plurality of times. As a result, the gear of the transmission is shifted.

  Thereafter, the acceleration processing unit 11b drives the clutch lever driving unit 34a so that the arm 34b pushes the clutch lever 104 forward, connects the clutch, and drives the throttle so that the arm 33b moves forward by a predetermined distance. The part 33a is driven. As a result, the throttle 103 rotates by a predetermined angle, and the motorcycle 100 is accelerated.

  The deceleration processing unit 11c controls the throttle drive unit 33a, the clutch lever drive unit 34a, and the change pedal drive unit 35a when the support mechanism control unit 11d or the measurement processing unit 11f described later determines that the motorcycle 100 should be decelerated. The motorcycle 100 is decelerated by being driven in a preset order.

  For example, the deceleration processing unit 11c outputs a signal that instructs the throttle driving unit 33a to rotate the throttle 103 in a direction opposite to that during acceleration by a predetermined rotation angle. As a result, the motorcycle 100 decelerates as the throttle opening decreases.

  Similarly to the acceleration processing unit 11b, the deceleration processing unit 11c may shift the gear of the transmission to decelerate the motorcycle 100. For example, the deceleration processing unit 11c drives the throttle drive unit 33a in a direction in which the rotation angle of the throttle 103 returns to the initial angle, and moves the clutch lever drive unit 34a so that the arm 34b pulls the clutch lever 104 forward. Drive and disengage the clutch. Thereafter, the deceleration processing unit 11c drives the change pedal driving unit 35a so that the arm 35b presses the change pedal 106 downward once or a plurality of times so that the arm 34b pushes the clutch lever 104 forward. The clutch lever driving unit 34a is driven to reconnect the clutch. Then, the throttle drive unit 33a is driven so that the arm 33b moves forward (rearward) by a predetermined distance. As a result, the motorcycle 100 is decelerated by the gear shift.

  The support mechanism control unit 11d determines whether or not the operating state of the motorcycle 100 on the traveling test table 4 satisfies a predetermined condition, and the motorcycle 100 by the support mechanisms 2 and 5 according to the determination result. The process of releasing the support or resuming the support is executed.

  For example, the support mechanism control unit 11d detects the traveling speed of the motorcycle 100 on the traveling test table 4 based on a signal input from the vehicle speed sensor 45 at a predetermined sampling period (for example, several tens of milliseconds). . Then, it is determined whether or not the traveling speed has reached a predetermined threshold value (hereinafter referred to as a support release speed (for example, several tens of kilomails per hour)). Here, the support release speed is a speed at which the motorcycle 100 can run independently (travel in a state in which the support is released from the side) by the gyro effect of the rotating front wheel 102 and the rear wheel 101.

  In the initial state (the state before the motorcycle starts running), the front wheel 102 is sandwiched between the support rods 21 and 22, and the rear wheel 101 is sandwiched between the support rods 51 and 52, whereby the motorcycle 100 is upright. It is supported in the state. The support mechanism control unit 11d maintains this state until the travel speed reaches the support release speed, and determines whether the travel speed has reached the support release speed. When the traveling speed reaches the support release speed, the support mechanism control unit 11d instructs the support rods 21 and 22 to move in the direction in which the distance between the support rods 21 and 22 increases (the direction indicated by F2 in FIG. 3). A signal is output to the support rod driving units 23 and 24. Similarly, the support mechanism control unit 11d drives the support rod drive units 53 and 54 to release the rear wheel 101 from being pinched by the support rods 51 and 52. Thus, the motorcycle 100 travels in a state where the support by the support mechanisms 2 and 5 is released.

  Thereafter, the support mechanism control unit 11d determines whether or not the traveling speed of the motorcycle 100 has become lower than the support release speed. When the measurement processing by the measurement processing unit 11f described later ends, the deceleration processing unit 11c decelerates the motorcycle 100, and when the traveling speed becomes lower than the support release speed, the support mechanism control unit 11d includes the support rod 21, A control signal for instructing the support rods 21 and 22 to move in the direction in which the interval 22 is narrowed (the direction indicated by F1 in FIG. 3) is output to the support rod driving units 23 and 24. Similarly, the support mechanism control unit 11d drives the support rod drive units 53 and 54 to resume the holding of the rear wheel 101 by the support rods 51 and 52. As a result, the motorcycle 100 travels while being supported from the side.

  In addition, the support mechanism control unit 11d determines whether the motorcycle 100 is in a state where the front wheels 102 and the rear wheels 101 are sandwiched between the support mechanisms 2 and 5 based on signals input from the support load detection units 25 and 26. It may be determined whether the operating state corresponds to a predetermined condition (hereinafter referred to as an appropriate operating condition). The process in this case is executed as follows, for example.

  The support mechanism control unit 11d is based on signals input from the support load detection units 25 and 26, and loads (hereinafter referred to as support loads) applied to the support rods 21 and 22 from the front wheel 102 at a predetermined sampling period. ) Is detected. Then, it is determined whether or not the support load is smaller than a predetermined reference value (hereinafter referred to as a support load reference value). Here, when the support load applied to the support rods 21 and 22 is smaller than the support load reference value, the support mechanism control unit 11d supports on the condition that the traveling speed has reached the above-described support release speed. The support of the motorcycle 100 by the mechanisms 2 and 5 is released. On the other hand, when the support load applied to one of the support rods 21 and 22 is equal to or greater than the support load reference value, it is determined that the operating state of the motorcycle 100 does not correspond to the appropriate operating condition. In this case, for example, the deceleration processing unit 11c decelerates the motorcycle 100 and stops the traveling test.

  Further, the support mechanism control unit 11d calculates a change amount of the support load per unit time, and determines whether or not the operation state of the motorcycle 100 corresponds to the appropriate operation condition based on the change amount. Also good. The process in this case is executed as follows, for example.

  When the support load applied to either of the support rods 21 and 22 is equal to or greater than the above-described support load reference value, the support mechanism control unit 11d immediately stops the running test and stops the support load at a predetermined sampling period. Continue detection. Then, every time the support load is detected, the amount of increase or decrease from the previously detected support load is calculated, and when those values exceed a predetermined upper limit value, the operating state of the motorcycle 100 becomes an appropriate operating condition. You may judge that it is not applicable.

  Note that the amount of change in the support load per unit time is not limited to the increase or decrease in the support load. For example, the number of times the support rod on which the support load is applied is switched from one support rod to the other. There may be.

  In addition, the support mechanism control unit 11d moves the support rods 21 and 22 and the support rods 51 and 52 in the direction in which the distance between the support rods 21 and 22 and the support rods 51 and 52 increases (when the support is released). The support rod drive units 23 and 24 and the support rod drive units 53 and 54 may be driven so that the distance between them becomes a size determined based on the operating state of the motorcycle 100.

  For example, the support mechanism control unit 11d is applied to the support rods 21 and 22 based on signals input from the support load detection units 25 and 26 when the traveling speed of the motorcycle 100 reaches the support release speed. Detect support load. Then, based on the support load, the intervals between the end portions 21a and 22a of the support rods 21 and 22 to be set and the end portions 51a and 52a of the support rods 51 and 52 (hereinafter referred to as set intervals) are calculated. This calculation process is executed as follows, for example.

  A formula indicating the relationship between the set interval and the support load is stored in the storage unit 12 in advance. Then, the support mechanism control unit 11d calculates the set interval by substituting the detected support load into the formula. A table in which the set interval and the support load are associated may be stored in the storage unit 12 in advance. Then, the support mechanism control unit 11d may calculate a set interval corresponding to the detected support load with reference to the table. In these formulas and tables, the set interval is determined so as to decrease as the support load increases, for example.

  After calculating the set interval, the support mechanism control unit 11d drives the support rod driving units 23 and 24 so that the intervals between the end portions 21a and 22a of the support rods 21 and 22 become the set interval. At the same time, the support rod driving units 53 and 54 are driven so that the interval between the end portions 51a and 52a of the support rods 51 and 52 becomes the set interval. For example, a table that associates the set interval with the drive time is stored in the storage unit 12 in advance. Then, the support mechanism control unit 11d drives the support rod drive units 23, 24, 53, and 54 for a drive time corresponding to the calculated set interval. By performing such processing, it is possible to suppress the motorcycle 100 from suddenly moving in the left-right direction (vehicle width direction) when the support by the support rods 21 and 22 is released.

  Further, the set interval may be determined in association with the traveling speed of the motorcycle 100. In this case, for example, a table that associates the set interval with the traveling speed is stored. Here, the set interval is determined to increase as the traveling speed increases, for example. The support mechanism control unit 11d detects the traveling speed of the motorcycle 100 at a predetermined sampling period based on a signal input from the vehicle speed sensor 45. And the support mechanism control part 11d acquires the setting space | interval corresponding to the detected travel speed with reference to the table mentioned above, the space | interval of the edge parts 21a and 22a of the support rods 21 and 22, and the support rods 51 and 52. The support rod drive units 23, 24, 53, and 54 are driven so that the intervals between the end portions 51a and 52a of the first and second end portions 51a and 52a become the set intervals.

  The vehicle behavior monitoring unit 11e determines whether or not the behavior of the vehicle meets a predetermined condition (hereinafter referred to as behavior permission condition). When the behavior of the vehicle no longer corresponds to the behavior permission condition, for example, the deceleration processing unit 11c decelerates the motorcycle 100 and stops the running test. The process of the vehicle behavior monitoring unit 11e is executed as follows, for example.

  The vehicle behavior monitoring unit 11e detects a rotational load applied to the handle 107 (hereinafter referred to as a handle load) on the basis of signals input from the handle load detection units 36 and 37 at a predetermined sampling period. It is determined whether or not the load is smaller than a predetermined threshold value (hereinafter referred to as a handle load allowable value). Then, when the detected handle load is equal to or greater than the handle load allowable value, it is determined that the behavior of the vehicle no longer corresponds to the behavior allowable condition.

  Further, the vehicle behavior monitoring unit 11e detects a support load applied to the support rods 21 and 22 based on signals input from the support load detection units 25 and 26 at a predetermined sampling period, and the support load is determined in advance. You may determine whether it is smaller than a threshold value (henceforth a support load allowable value). Then, when the detected support load becomes equal to or greater than the support load allowable value, it may be determined that the behavior of the vehicle no longer corresponds to the behavior allowable condition.

  The measurement processing unit 11f measures the behavior of the motorcycle 100 in a state where the support of the motorcycle 100 is released by the process executed by the support mechanism control unit 11d. In the example described here, the measurement processing unit 11f is in a state in which the support of the motorcycle 100 is released and the traveling speed is set to a speed set by the test operator (hereinafter referred to as a test condition speed). Based on the signals input from the handle load detectors 36 and 37, the handle load applied to the handle 107 is detected at a predetermined sampling period. Then, the handle load is stored in the storage unit 12 in association with information indicating the detected time or displayed on the display unit 15.

  Here, the flow of processing executed by the control unit 11 will be described. FIG. 7 is a flowchart illustrating an example of processing executed by the control unit 11. In the example described here, it is assumed that the motorcycle 100 is supported by the support mechanism 2 and the support mechanism 5 in the initial state.

  First, the acceleration processing unit 11b activates the throttle drive unit 33a and the clutch lever drive unit 34a to start a simulated running of the motorcycle 100 (S101). For example, when the transmission is set to the first speed as the initial state and the clutch lever 104 is pulled toward the front (the clutch is disengaged), the acceleration processing unit 11b operates the throttle driving unit 33a. Then, the throttle opening is raised, and the clutch lever driving unit 34a is operated so that the arm 34b of the clutch lever operating mechanism 34 moves forward, thereby engaging the clutch.

  Thereafter, the support mechanism control unit 11d detects a support load applied to the support rods 21 and 22 based on signals input from the support load detection units 25 and 26, and whether or not the support load is smaller than a support load reference value. Is determined (S102). Here, when the support load applied to any of the support rods is equal to or greater than the support load reference value, the support mechanism control unit 11d detects the support load at a predetermined sampling period, and the change amount of the support load is determined in advance. It is determined whether or not the value is smaller than a predetermined upper limit value (S103). When the change amount of the support load is equal to or greater than the upper limit value, the driving of the motorcycle 100 is finished without performing a running test. Specifically, the deceleration processing unit 11c operates the throttle driving unit 33a, the clutch lever driving unit 34a, and the change pedal driving unit 35a in a predetermined order to stop the motorcycle 100 (S115). On the other hand, if the change amount of the support load is smaller than the upper limit value as a result of the determination in S103, the acceleration processing unit 11b moves the throttle drive unit 33a, the clutch lever drive unit 34a, and the change pedal drive unit 35a in a predetermined order. Is operated to accelerate the motorcycle 100 (S104).

  If the support load is smaller than the support load reference value as a result of the determination in S102, the support mechanism control unit 11d detects the travel speed of the motorcycle 100 based on the signal input from the vehicle speed sensor 45, and the travel It is determined whether or not the speed has reached the support release speed (S105). Here, when the traveling speed has not yet reached the support release speed, the acceleration processing unit 11b operates the throttle driving unit 33a, the clutch lever driving unit 34a, and the change pedal driving unit 35a in a predetermined order. The motorcycle 100 is accelerated (S106).

  As a result of the determination in S105, when the traveling speed of the motorcycle 100 has reached the support release speed, the support mechanism control unit 11d increases the distance between the support rods 21 and 22 and the distance between the support rods 51 and 52. The support rod drive units 23, 24, 53, and 54 are driven to release the support of the motorcycle 100 by the support mechanisms 2 and 5 (S107). At this time, the support mechanism control unit 11d drives the support rod driving units 23, 24, 53, and 54 so that the support rods 21, 22, 51, and 52 move by a predetermined distance, for example. Further, as described above, when the traveling speed reaches the support release speed, the support load applied to the support rods 21 and 22 is detected. Then, the support rod driving units 23, 24, 53, and 54 may be driven so that the interval between the support rods 21 and 22 and the interval between the support rods 51 and 52 become set intervals corresponding to the detected support load. .

  Thereafter, the vehicle behavior monitoring unit 11e determines whether or not the behavior of the vehicle satisfies the behavior permission condition (S108). For example, as described above, the vehicle behavior monitoring unit 11e determines whether or not the handle load detected based on the signals input from the handle load detection units 36 and 37 is smaller than the handle load allowable value. Moreover, you may determine whether the support load detected based on the signal input from the support load detection parts 25 and 26 is smaller than a support load allowable value. Here, when the behavior of the vehicle corresponds to the behavior permission condition, the measurement processing unit 11f determines whether or not the driving state of the motorcycle 100 corresponds to the test condition (S109). For example, the measurement processing unit 11f determines whether or not the traveling speed of the motorcycle 100 has reached the test condition speed. Here, when the traveling speed has not yet reached the test condition speed, the acceleration processing unit 11b operates the throttle driving unit 33a, the clutch lever driving unit 34a, and the change pedal driving unit 35a in a predetermined order, The motorcycle 100 is further accelerated (S110). Thereafter, in S108, the vehicle behavior monitoring unit 11e determines again whether the behavior of the vehicle meets the behavior permission condition.

  On the other hand, if it is determined in S109 that the driving state of the motorcycle 100 corresponds to the test condition, the measurement processing unit 11f executes a measurement process of the behavior of the vehicle (S111). For example, as described above, the handle load is detected at a predetermined sampling period based on the signals input from the handle load detection units 36 and 37, and the handle load is stored in association with the time information indicating the detected time. They are stored in the unit 12 or displayed on the display unit 15.

  Thereafter, when the measurement processing by the measurement processing unit 11f is completed, the deceleration processing unit 11c operates the throttle driving unit 33a, the clutch lever driving unit 34a, and the change pedal driving unit 35a in a predetermined order to decelerate the motorcycle 100. (S112). Then, the support mechanism control unit 11d detects the traveling speed of the motorcycle 100 based on the signal input from the vehicle speed sensor 45, and determines whether or not the traveling speed has been reduced to the support release speed (S113). . Here, when the vehicle has not yet decelerated to the support release speed, the deceleration processing unit 11c executes the process of S112 again to further decelerate the motorcycle 100.

  As a result of the determination in S113, when it is determined that the traveling speed of the motorcycle 100 has decreased to the support release speed, the support mechanism control unit 11d drives the support rod drive units 23, 24, 53, and 54, The support of the motorcycle 100 by the support mechanisms 2 and 5 is resumed (S114). Thereafter, the deceleration processing unit 11c. The motorcycle 100 is decelerated until the motorcycle 100 stops (S115).

  As a result of the determination in S108, if the behavior of the vehicle does not correspond to the behavior permission condition, the deceleration processing unit 11c is not executed without executing the subsequent measurement processing by the measurement processing unit 11f (S111 in this case). However, the motorcycle 100 is decelerated (S112), and the support mechanism control unit 11d and the deceleration processing unit 11c execute the subsequent processes.

  Further, the vehicle behavior monitoring unit 11e determines whether or not the behavior of the vehicle satisfies the behavior permission condition at a predetermined cycle even when the measurement processing unit 11f is measuring the behavior of the vehicle in S111. Also good. Then, when the behavior of the vehicle no longer corresponds to the behavior allowable condition, the measurement processing unit 11f stops the measurement processing for the behavior of the vehicle, and the deceleration processing unit 11c decelerates the motorcycle 100 to control the support mechanism. The part 11d may resume supporting the motorcycle 100 by the support mechanisms 2 and 5. The above is an example of the process which the control part 11 performs in a driving | running | working test.

  The control unit 11 sets a value detected based on signals input from the support load detection units 25 and 26 before the running test of the motorcycle 100 is started as an initial value (for example, zero), and is during the running test. The difference between the detected value and the initial value may be used as the support load. Similarly, the control unit 11 sets a value detected based on signals input from the handle load detection units 36 and 37 before the running test of the motorcycle 100 is started as an initial value, and is detected during the running test. The difference between the value and the initial value may be used as the handle load.

  According to the present invention, when the traveling speed of the motorcycle 100 reaches the support release speed, the support of the motorcycle 100 by the support mechanisms 2 and 5 is released, and the motorcycle 100 continues to travel in this state. This makes it possible to diversify vehicle test items (here, steering wheel load).

  The present invention is not limited to the traveling test system 1 described above, and various modifications are possible.

  For example, in the traveling test system 1 described above, the steering robot 3 controls the motorcycle 100 to drive the motorcycle 100 to rotate the rear wheel 101, and the rear wheel rollers 42a and 42b and The front wheel rollers 41a and 41b rotate. However, a motor is connected to the rear wheel rollers 42a and 42b and the front wheel rollers 41a and 41b, and the motors are driven to rotate the rear wheel rollers 42a and 42b and the front wheel rollers 41a and 41b. Accordingly, the front wheel 102 and the rear wheel 101 of the motorcycle 100 may be rotated.

  In the traveling test system 1 described above, the support mechanism 2 includes support rods 21 and 22, and the support mechanism 5 includes support rods 51 and 52. These rods cause the front wheel 102 and the rear wheel 101 to be viewed from the side. The motorcycle 100 was supported by holding. However, the support mechanism for supporting the motorcycle 100 is not limited to this. For example, the support mechanism may support the control robot 3 and the motorcycle 100 by sandwiching the body 31 of the control robot 3 placed on the motorcycle 100 from the side.

  FIG. 8 is a schematic diagram of a traveling test system 1A that is an example of the traveling test system according to this embodiment, and shows a state in which the motorcycle 100 to be tested faces from the side. FIG. 9 is a schematic diagram of the control robot 3 and the support mechanism 200 in this embodiment, and shows a state in which they are viewed from above. In these drawings, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals, and the support rod drive unit for moving the support rods 210 and 220 sandwiching the body 31 in the vehicle width direction is omitted. . Further, in the travel test system 1A, the process executed by the control device 10 is the same as the process executed in the travel test system 1 described above, and a description thereof will be omitted here.

  The travel test system 1A shown in FIGS. 8 and 9 includes the support mechanism 200 described above, and support load detection units 250 and 260 are attached to the support mechanism 200 (see FIG. 9).

  The support rods 210 and 220 are arranged so that the longitudinal direction thereof is in the vehicle width direction (the direction indicated by B in FIG. 9). The end portions 210a and 220a face each other with a gap provided therebetween. During the running test of the motorcycle 100, the body 31 of the control robot 3 placed on the motorcycle 100 is disposed in the gap. For example, plate-like support members 210b and 220b are attached to the end portions 210a and 220a, and the longitudinal direction of the support members 210b and 220b is directed in the front-rear direction (the direction indicated by A in FIG. 8).

  A support rod drive unit (not shown) is driven according to a signal input from the control device 10. The support rods 210 and 220 are driven in the direction in which the distance between the end portions 210a and 220a is narrowed (the direction indicated by F1 in FIG. 9) or the direction in which the gap is widened (the direction indicated by F2 in FIG. 9). Move to. Thus, the support rods 210 and 220 support the motorcycle 100 or release the support by sandwiching the body 31 or separating from the body 31.

  The support load detection units 250 and 260 include, for example, a strain sensor and a pressure sensor, like the support load detection units 25 and 26 described above, and support rods 210 from the motorcycle 100 via the trunk portion 31 during a running test. , 220 is detected. Then, an electrical signal corresponding to the support load is output to the control device 10. In the example described here, the support load detection units 250 and 260 are attached to midway portions of the support rods 210 and 220, and detect strain and pressure generated in the support rods 210 and 220.

  In the traveling test systems 1 to 1A described above, the control device 10 detects the handle load based on the signals input from the handle load detection units 36 and 37. However, the steering robot may be provided with a handle rotation angle detection unit that detects the rotation angle (steering angle) of the handle 107.

  FIG. 10 is a schematic diagram of the traveling test system 1B according to this embodiment, and shows the state in which the motorcycle 100 is viewed from the side. FIG. 11 is a schematic diagram of the control robot 300 provided in the traveling test system 1B, and shows a state where the control robot 300 is viewed from above. In these drawings, the same portions as those described so far are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIGS. 10 and 11, the control robot 300 includes a handle rotation angle detection unit 380. The handle rotation angle detection unit 380 is, for example, a potentiometer, and is attached to the steering shaft 108 that rotatably supports the handle 107. The handle rotation angle detector 380 outputs an electrical signal corresponding to the rotation angle of the handle 107 to the control device 10.

  In the control robot 300, the throttle operation mechanism 33 and the clutch lever operation mechanism 34 are configured to allow the handle 107 to rotate. For example, the support member 33 f that supports the arm 33 e is slidable in the front-rear direction (the direction indicated by D in FIG. 11) with respect to the rod 39 that extends forward from the body portion 31. The arm 33e is rotatably connected to the support member 33f at the connecting portion 33g. Similarly, the support member 34 f that supports the arm 34 e is slidable in the front-rear direction with respect to the rod 39 that extends forward from the body portion 31. The arm 34e is rotatably connected to the support member 34f at the connecting portion 34g.

  Thus, when the control robot 300 and the handle rotation angle detection unit 380 are configured, the vehicle behavior monitoring unit 11e and the measurement processing unit 11f operate as follows, for example. In this embodiment as well, other processes (here, the acceleration processing unit 11b, the deceleration processing unit 11c, and the support mechanism control unit 11d) executed by the control unit 11 are the same as those described so far. Description is omitted.

  The vehicle behavior monitoring unit 11e detects the steering wheel load based on signals input from the steering wheel load detection units 36 and 37 at a predetermined sampling period, and handles the steering wheel based on a signal input from the steering wheel rotation angle detection unit 380. A rotation angle 107 (hereinafter referred to as a handle rotation angle) is detected. Then, it is determined whether or not the handle rotation angle is smaller than a predetermined threshold value (hereinafter referred to as a handle rotation angle allowable value). When the detected steering wheel rotation angle is greater than or equal to the steering wheel rotation angle allowable value, it is determined that the behavior of the vehicle no longer corresponds to the behavior allowable condition.

  In addition, the measurement processing unit 11f is input from the steering wheel rotation angle detection unit 380 in a state where the support of the motorcycle 100 is released by the processing of the support mechanism control unit 11d and the traveling speed becomes the test condition speed. Based on the signal, the steering wheel rotation angle is detected at a predetermined sampling period. The handle rotation angle is stored in the storage unit 12 or displayed on the display unit 15 in association with information indicating the detected time.

  In the running test systems 1 and 1A, for example, disturbance (for example, a force in the left-right direction or the front-rear direction) may be applied to the motorcycle 100 in a state where the support of the motorcycle 100 is released. The measurement processing unit 11f detects the handle load based on signals input from the handle load detection units 36 and 37, and stores the handle load in the storage unit 12 in association with information indicating the detected time. Or may be displayed on the display unit 15.

  Similarly, in the running test system 1B, disturbance may be applied to the motorcycle 100 in a state where the support of the motorcycle 100 is released. Then, the measurement processing unit 11f detects the handle rotation angle based on the signal input from the handle rotation angle detection unit 380, and stores the handle rotation angle in the storage unit 12 in association with information indicating the detected time. Or may be displayed on the display unit 15.

It is a mimetic diagram of a run test system concerning one embodiment of the present invention, and shows signs that a motorcycle used as a test object is faced from the side. It is a figure which shows a mode that the control robot with which the said driving test system is provided faces from upper direction. It is a typical top view of the support mechanism with which the above-mentioned run test system is provided. It is a typical top view of the support mechanism with which the above-mentioned run test system is provided. It is a block diagram which shows the structure of the control apparatus with which the said driving test system is provided. It is a functional block diagram of the control part with which the said control apparatus is provided. It is a flowchart which shows the process which the said control part performs. It is a schematic diagram of the driving | running | working test system which concerns on other embodiment of this invention, and shows a mode that the motorcycle used as a test object faces from the side. It is a figure which shows a mode that the steering robot and support mechanism with which the driving | running | working test system shown in FIG. It is a schematic diagram of the driving | running | working test system which concerns on other embodiment of this invention, and shows a mode that the motorcycle used as a test object faces from the side. It is a figure which shows a mode that the control robot with which the driving | running | working test system shown in FIG.

Explanation of symbols

  1, 1A, 1B Travel test system, 2,200 Support mechanism, 3,300 Control robot (control device), 4 Travel test table, 5 Support mechanism, 10 Control device, 11 Control unit, 11a Control robot control unit, 11b Acceleration Processing unit, 11c deceleration processing unit, 11d support mechanism control unit (control means), 11e vehicle behavior monitoring unit, 11f measurement processing unit (measurement unit), 12 storage unit, 13 interface unit, 14 input unit, 15 display unit, 21 , 22, 51, 52, 210, 220 Support rod, 23, 24, 53, 54 Support rod drive unit, 25, 26 Support load detection unit, 27, 57 Roller, 28, 29, 58, 59 Housing, 31 body Part, 32 leg part, 33 throttle operation mechanism, 34 clutch lever operation mechanism, 35 change pedal operation mechanism, 36, 37 handle Heavy detection section (behavior detection means), 41a, 41b front wheel roller, 42a, 42b rear wheel roller, 43 belt, 45 speed sensor (speed detection means), 100 motorcycle, 101 rear wheel, 102 front wheel, 103 throttle 104 clutch lever, 105 steps, 106 change pedal, 107 handle, 108 steering shaft, 109 grip, 380 handle rotation angle detector (behavior detector).

Claims (7)

A running test stand for simulating a motorcycle to be tested;
A support mechanism for supporting a motorcycle driven on the running test table;
Speed detecting means for detecting a simulated running speed of the motorcycle on the running test table;
Control means for controlling the support mechanism,
The support mechanism is configured to be capable of releasing support of the motorcycle,
The control means releases the support of the motorcycle by the support mechanism according to the traveling speed detected by the speed detection means.
Motorcycle running test system characterized by the above. The travel test system according to claim 1,
A steering device that is provided on the motorcycle and that controls the motorcycle;
Motorcycle running test system characterized by the above. The traveling test system for a motorcycle according to claim 2,
The support mechanism supports the motorcycle on the running test stand by supporting the steering device provided on the motorcycle,
The travel test system further includes a load detection unit that detects a load applied to the support mechanism from the control device.
Motorcycle running test system characterized by the above. The traveling test system for a motorcycle according to claim 2,
Behavior detecting means for detecting the behavior of the motorcycle;
Measuring means for measuring the behavior of the motorcycle detected by the behavior detecting means in a state where the support of the motorcycle by the support mechanism is released;
Motorcycle running test system characterized by the above. The traveling test system for a motorcycle according to claim 4,
The behavior detection means is provided in the control device.
Motorcycle running test system characterized by the above. The motorcycle according to claim 4,
A handle load detecting means for detecting a load applied to a handle of the motorcycle as the behavior detecting means;
Motorcycle running test system characterized by the above. The motorcycle according to claim 4,
A steering wheel rotation angle detection unit that detects a rotation angle of a handle of the motorcycle as the behavior detection unit;
Motorcycle running test system characterized by the above.

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