JP2017196962A - bus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bus which enables easy correct seating.SOLUTION: A bus 1 comprises first to forth sensors 11 to 14 which are located on one lateral face 1a in a width direction D1 of the bus 1 and detect a reference line 4 on said one lateral face 1a side of the bus 1. A detection position P1 of the first sensor 11 is separated from a detection position P2 of the second sensor 12 by only a detection width W2 on a side opposite to the bus 1 in the width direction D1, and a detection position P3 of the third sensor 13 is arranged along with the detection position P1 of the first sensor 11 in a cross direction D2 of the bus 1 and is separated from a detection position P4 of the forth sensor 14 by only a detection width W2 on a side opposite to the bus 1 in the width direction D1. The detection width W2 is wider than a width W1 of the reference line 4.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a bus.

  For example, in a route bus as described in Patent Document 1, a user gets on and off a bus that stops at a stop. Patent Document 1 describes a boarding support device that notifies a user waiting for a route bus at a bus stop that a scheduled route bus arrives.

Japanese Patent Laying-Open No. 2015-56081

  By the way, when stopping a bus at a stop, it is required to stop without leaving a gap of a predetermined width or more between the bus and the stop. Stopping without leaving a gap of a predetermined width or more between the bus and the bus stop is called “direct arrival”. However, a high level of skill is required of the driver in order to ensure that the bus arrives properly. Therefore, there is a demand for a technique for easily wearing a bus.

  In view of the above, an object of one aspect of the present invention is to provide a bus that can be easily put on.

  A bus according to one aspect of the present invention is a bus that travels along a reference line provided at a bus stop, and is disposed on one side of the width direction of the bus, and detects a reference line on one side of the bus. 1 to 4 sensors, the detection position of the first sensor is separated from the detection position of the second sensor by the detection width on the opposite side to the bus in the width direction, and the detection position of the third sensor is the first sensor The detection positions are arranged in the front-rear direction of the bus, and are separated from the detection position of the fourth sensor by the detection width on the side opposite to the bus in the width direction, and the detection width is wider than the width of the reference line.

  In this bus, a reference line provided at a stop is detected by first to fourth sensors arranged on one side surface of the bus in the width direction. On one side of the bus, the detection positions of the first and third sensors are separated from the detection positions of the second and fourth sensors by a detection width on the side opposite to the bus in the width direction, and the first and third sensors The detection positions are arranged in the front-rear direction of the bus. This detection width is wider than the width of the reference line. Thereby, for example, when the bus is traveling along the reference line, the reference line is positioned between the detection positions of the first and second sensors, and between the detection positions of the third and fourth sensors. By steering the bus so that the reference line is located, the bus can be positioned in the width direction with respect to the reference line at each of the detection positions of the first and second sensors and the detection positions of the second and fourth sensors. it can. Therefore, by setting in advance the positional relationship between the reference line and the detection position of each sensor so that no gap of a predetermined width or more is formed between the bus and the bus stop, the bus is placed between the bus and the bus stop. The vehicle can be run without leaving a gap of a predetermined width or more, and the bus can be easily put on.

  The detection position of the first sensor and the detection position of the third sensor may be separated from the wheel base of the bus in the front-rear direction. As a result, the bus can be positioned in the width direction with respect to the reference line at two positions that are separated from the wheel base of the bus in the front-rear direction.

  The first to fourth sensors may be infrared sensors. As a result, the reference line can be detected even at night, so that the bus can be put on even at night.

  The bus according to one aspect of the present invention further includes a steering control unit that controls the steering of the bus based on the detection results of the first to fourth sensors, and the steering control unit is configured such that the bus travels along the reference line. The reference line is located between the detection position of the first sensor and the detection position of the second sensor, and the reference line is located between the detection position of the third sensor and the detection position of the fourth sensor. In this way, the steering of the bus may be controlled. In this case, for example, it is possible to make the bus arrive more easily than when the driver steers the bus based on the detection results of the first to fourth sensors.

  The bus according to one aspect of the present invention further includes an imaging unit that is attached to the bus and images a predetermined range including the one side surface, and the steering control unit is configured to detect the position of one side surface and the reference line in the image captured by the imaging unit. Based on the position, the steering of the bus may be controlled so that the bus travels along the reference line. Thus, after the bus travels along the reference line by the steering control based on the image captured by the imaging unit, the bus is moved between the stop and the stop by the steering control based on the detection results of the first to fourth sensors as described above. Since it is possible to travel without leaving a gap of a predetermined width or more, it is possible to make the bus even more easily attached.

  According to the present invention, it is possible to provide a bus that can be easily put on.

It is a side view of the bus concerning one embodiment of the present invention. (A) is the perspective view of a stop, (b) is the figure which looked at the stop and the bus from the rear side of the front-back direction. (A) is the figure which looked at the bus stop and bus from the rear side in the front-rear direction, and (b) is a cross-sectional view showing the mounting position of each sensor. It is a top view which shows the detection position of a 1st-4th sensor. (A) is an enlarged view of the left side mirror part of FIG. 1, (b) is a schematic diagram which shows the example of the image imaged by the imaging part of (a). It is a flowchart which shows the processing flow by a steering control part. It is the enlarged view which looked at the stop and the bus from the rear side in the front-back direction.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, the same reference numerals are used for the same or corresponding elements, and duplicate descriptions are omitted.

  The bus 1 shown in FIG. 1 is a large bus such as a route bus. For example, the bus 1 circulates a plurality of stops 2 shown in FIG. 2 and stops at each stop 2. A user of the bus 1 gets on and off the bus 1 stopped at the stop 2.

  2A and 2B, the upper surface 2a of the stop 2 is higher than the road surface 3 (for example, lane) on which the bus 1 travels, and the upper surface 2a of the stop 2 and the road surface 3 is formed with a step surface 2b. The height of the upper surface 2a from the road surface 3 is preferably approximately the same as the height from the road surface 3 of the entrance of the bus 1, for example, in order to make it easier for the user to get on and off.

  The stop 2 is provided with a belt-like reference line 4 along the boundary between the upper surface 2a and the step surface 2b. The reference line 4 is provided over the upper surface 2a and the step surface 2b, and extends linearly. The reference line 4 is provided over the entire area of the stop 2, and is extended to the rear side (left side in FIG. 2) of the stop 2 in the vehicle traveling direction. The reference line 4 is provided, for example, on the curb of the road surface 3 on the rear side of the stop 2 in the vehicle traveling direction. The length of the reference line 4 is about 70 m, for example. In plan view, the width W1 of the reference line 4 is, for example, about 20 mm. The reference line 4 can be detected by first to fourth sensors 11 to 14 described later, and can be imaged by a camera 15 described later. The reference line 4 is formed of a paint that can be detected by an infrared sensor and an infrared camera, for example, and is a white line, for example.

  As shown in FIG. 2B, at the bus stop 2, the bus 1 stops so that one side surface (left side surface) 1 a in the width direction D <b> 1 is along the reference line 4. For example, when the bus 1 stops at the stop 2, the bus 1 gradually approaches the stop 2 so that the one side 1 a approaches the reference line 4 from the state of traveling in the lane, and the one side 1 a follows the reference line 4. Stop in the state. From the viewpoint of barrier-free, it is preferable that the bus 1 stops (fixed arrival) without leaving a gap of a predetermined width or more between the bus 1 and the bus stop 2. For example, according to one standard, the distance L between the side surface 1a and the stop 2 (the boundary between the upper surface 2a and the step surface 2b) when the bus 1 stops is preferably in the range of 40 mm ± 20 mm. .

  Next, the bus 1 will be described. As shown in FIG. 1, the bus 1 includes a first sensor 11, a second sensor 12, a third sensor 13, a fourth sensor 14, a camera (imaging unit) 15, and a steering control unit 16. ing.

  The first to fourth sensors 11 to 14 are disposed on one side 1 a of the bus 1. In FIG. 1, positions where the first to fourth sensors 11 to 14 are arranged are indicated by reference signs A <b> 1 to A <b> 4. This also applies to FIG. 3A described later. The first and second sensors 11 and 12 are arranged side by side in the vertical direction on the front side (left side in FIG. 1) in the front-rear direction D2 of the bus 1 relative to the front wheel 1b of the bus 1. The second sensor 12 is disposed below the one side surface 1 a, and the first sensor 11 is disposed above the second sensor 12. The third and fourth sensors 13 and 14 are arranged in the vertical direction on the rear side in the front-rear direction D2 with respect to the rear wheel 1c of the bus 1. The fourth sensor 14 is disposed below the one side surface 1 a, and the third sensor 13 is disposed above the fourth sensor 14. The first sensor 11 and the third sensor 13 are arranged in the front-rear direction D2, and the second sensor 12 and the fourth sensor 14 are arranged in the front-rear direction D2.

  As shown in FIGS. 3A and 4, the first to fourth sensors 11 to 14 detect the reference line 4 on the side surface 1 a side of the bus 1. The first to fourth sensors 11 to 14 are, for example, infrared sensors, emit infrared light, receive reflected light, and detect the reference line 4 based on the received light intensity. As shown in FIG. 3 (b), the first sensor 11 has a wall portion constituting one side 1a so as not to protrude from one side 1a of the bus 1 to the outside of the vehicle body (left side in FIG. 3 (a)). 1d. The first sensor 11 is disposed so that the emission port faces the lower side of the vehicle body and the outer side of the vehicle body, and emits infrared light toward the lower side of the vehicle body and the outer side of the vehicle body. Similarly to the first sensor 11, the second to fourth sensors 12 to 14 are arranged so as not to protrude from the side surface 1 a to the outside of the vehicle body, and emit infrared light to the lower side of the vehicle body and toward the outside of the vehicle body. . Moreover, the directions (infrared emission directions) of the first to fourth sensors 11 to 14 are parallel to each other.

  As shown in FIG. 4, the detection position P1 of the first sensor 11 is separated from the detection position P2 of the second sensor 12 by the detection width W2 on the side opposite to the bus 1 in the width direction D1 (outside). The detection position P3 of the third sensor 13 is separated from the detection position P4 of the fourth sensor 14 by the detection width W2 outside the width direction D1. In this example, the detection positions P1, P2 are arranged in the width direction D1, and the detection positions P3, P4 are arranged in the width direction D1. The detection position P3 is aligned with the detection position P1 in the front-rear direction D2. The detection position P1 is located on a straight line passing through the first sensor 11 and orthogonal to the side surface 1a in plan view. Similarly, each of the detection positions P2 to P4 is located on a straight line passing through the second to fourth sensors 12 to 14 and orthogonal to the one side surface 1a in plan view. The detection position P1 and the detection position P3 are separated from each other by at least the wheel base WB (FIG. 1) of the bus 1. The detection width W2 is wider than the width W1 of the reference line 4. The detection width W2 is set to about 40 mm, for example.

  The camera 15 is disposed on one side 1 a of the bus 1. As shown in FIG. 5A, the camera 15 is attached to, for example, the lower end portion of the left side mirror portion 6 of the bus 1 so that the photographing direction is the rear side of the front-rear direction D2. As illustrated in FIG. 5B, the camera 15 is an imaging unit that captures a predetermined range including the one side surface 1 a and acquires an image 20. The camera 15 captures an image 20 including the one side surface 1a and the reference line 4 when the bus 1 approaches the stop 2. The camera 15 is an infrared camera having sensitivity to infrared light, for example.

  The steering control unit 16 is disposed inside the bus 1 and controls the steering of the bus 1 based on the detection results of the first to fourth sensors 11 to 14 and the camera 15. The steering control unit 16 is configured by, for example, an ECU (Electronic Control Unit). The ECU is an electronic control unit having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a CAN (Controller Area Network) communication circuit, and the like. The steering control unit 16 implements various functions by loading a program stored in the ROM into the RAM and executing the program loaded in the RAM by the CPU. A steering actuator 17 is connected to the steering control unit 16 via a CAN communication circuit.

  The steering actuator 17 changes the steering angle of the bus 1 based on a control signal from the steering control unit 16. The steering actuator 17 is a motor actuator provided on the steering shaft, for example, and changes the steering angle of the bus 1 by rotating the steering shaft. The steering actuator 17 may be an assist motor of an electric power steering system, for example.

  Next, processing by the steering control unit 16 will be described with reference to FIG. In the present embodiment, the steering control unit 16 causes the bus 1 to approach the reference line 4 when the bus 1 gradually approaches the stop 2 so that the one side surface 1a approaches the reference line 4 from the state where the bus 1 is traveling in the lane. The steering of the bus 1 is controlled so as to travel along the road. In this state, for example, when the driver applies a brake, the bus stops at the stop. That is, the driver, for example, visually confirms the distance between the bus 1 and the target stop position in the front-rear direction D2, and applies the brake at a predetermined timing. For example, the driver controls the accelerator. Hereinafter, processing by the steering control unit 16 will be described. The processing by the steering control unit 16 may be started, for example, when an ignition switch is turned on, or may be started by a switch operation.

  After the start of processing, the steering control unit 16 first determines whether or not the reference line 4 is located in the image 20 captured by the camera 15 (step S1). As a result of the determination, if it is determined that the reference line 4 is located in the image 20 (YES in step S1), the process proceeds to step S2, and if it is determined that the reference line 4 is not located in the image 20 (step If NO in S1, the process returns to step S1.

  In step S2, the steering control unit 16 performs steering control based on the image 20 (step S2). Specifically, the steering control unit 16 controls the steering of the bus 1 so that the bus 1 travels along the reference line 4 based on the position of the one side surface 1 a and the position of the reference line 4 in the image 20. . For example, the steering control unit 16 changes the steering angle of the bus 1 by a predetermined angle so that the one side surface 1a and the reference line 4 gradually approach parallel and the one side surface 1a and the reference line 4 gradually approach each other. .

  Subsequently, the steering control unit 16 determines whether or not the reference line 4 is detected by the first sensor 11 (step S3). As a result of the determination, when it is determined that the reference line 4 is detected by the first sensor 11 (YES in step S3), the process proceeds to step S4, and when it is determined that the reference line 4 is not yet detected by the first sensor 11 ( NO at step S3), the process returns to step S2.

  In step S4, the steering control unit 16 performs steering control based on the detection results of the first sensor to the fourth sensor 11-14. Specifically, as shown in FIG. 7, the steering control unit 16 has the reference line 4 between the detection position P1 of the first sensor 11 and the detection position P2 of the second sensor 12, and the third The steering of the bus 1 is controlled so that the reference line 4 is located between the detection position P3 of the sensor 13 and the detection position P4 of the fourth sensor 14.

  For example, the steering control unit 16 first changes the steering angle of the bus 1 so that the one side surface 1a gradually approaches the reference line 4 from the state where the detection positions P1 and P3 are located on the reference line 4. Thus, the detection positions P1, P3 are moved to the outside of the width direction D1, and the detection positions P1, P3 are positioned outside the reference line 4. Subsequently, in the steering control unit 16, the detection positions P1 and P3 are located outside the width direction D1 with respect to the reference line 4, and the detection positions P2 and P4 are located inside the width direction D1 with respect to the reference line 4. The steering of the bus 1 is controlled so that the running state is maintained. For example, when the detection position P2 or the detection position P4 moves on the reference line 4 from the state, the steering control unit 16 changes the steering angle of the bus 1 so that the one side surface 1a gradually moves away from the reference line 4. As a result, the detection position P2 or the detection position P4 is moved to the outside in the width direction D1, and the detection positions P2 and P4 are returned to the state in which they are located inside the width direction D1 with respect to the reference line 4. With the above processing, the bus 1 travels along the reference line 4 without leaving a gap of a predetermined width or more with the stop 2.

  As described above, in the bus 1, the reference line 4 provided in the stop 2 is detected by the first to fourth sensors 11 to 14 arranged on the one side surface 1 a of the width direction D <b> 1 of the bus 1. On one side 1a side of the bus 1, the detection positions P1, P3 of the first and third sensors 11, 13 are the same as the bus 1 in the width direction D1 from the detection positions P3, P4 of the second and fourth sensors 13, 14. The detection positions P1 and P3 are arranged in the front-rear direction D2 of the bus 1 and are separated on the opposite side (outside) by the detection width W2. The detection width W2 is wider than the width W1 of the reference line 4. Thereby, for example, when the bus 1 is traveling along the reference line 4, the reference line 4 is positioned between the detection positions P1 and P2, and the reference line 4 is positioned between the detection positions P3 and P4. By steering the bus 1 in such a manner, the bus 1 can be positioned in the width direction D1 with respect to the reference line 4 at each of the detection positions P1, P2 and the detection positions P3, P4. Therefore, as in the above embodiment, the positional relationship between the reference line 4 and the detection positions P1 to P4 is set in advance so that no gap of a predetermined width or more is formed between the bus 1 and the stop 2 in that state. Thus, the bus 1 can be run without leaving a gap of a predetermined width or more between the bus 1 and the bus stop 2, and the bus 1 can be easily put on the front.

  If there is a large gap between the bus 1 and the bus stop 2, the user may not step on the wheel, and the front wheel of the wheelchair may be caught when there is a user who uses the wheelchair. Although it is conceivable to install a transfer plate between the bus 1 and the bus stop 2 in order to prevent the front wheel of the wheelchair from being caught, the work load on the driver increases. On the other hand, in the bus 1 of the present embodiment, the bus 1 can be run without leaving a gap of a predetermined width or more between the bus 1 and the bus stop 2, and the bus 1 can be easily put on the bus. Therefore, the occurrence of such a situation can be suppressed.

  Further, in the bus 1, the detection position P1 and the detection position P3 are separated from the wheel base WB in the front-rear direction D2, and the bus 1 is separated from the reference line 4 at two positions separated from the wheel base WB in the front-rear direction D2. Since the positioning in the width direction D1 can be performed, the bus 1 can be correctly attached.

  In the bus 1, the first to fourth sensors 11 to 14 are infrared sensors, and the reference line 4 can be detected even at night, so that the bus 1 can be put on at night.

  The bus 1 also includes a steering control unit 16 that controls the steering of the bus 1 based on the detection results of the first to fourth sensors 11 to 14. In this case, for example, the bus 1 can be put on more easily than when the driver steers the bus 1 based on the detection results of the first to fourth sensors 11 to 14.

  Further, in the bus 1, the steering control unit 16 causes the bus 1 to travel along the reference line 4 based on the position of one side surface in the image 20 captured by the camera 15 and the position of the reference line 4. To control the steering. Thereby, after driving the bus 1 along the reference line 4 to some extent by the steering control based on the image 20, the bus 1 is moved by the steering control based on the detection results of the first to fourth sensors 11 to 14 as described above. Since it is possible to travel without leaving a gap of a predetermined width or more between the bus 2 and the bus stop 2, it is possible to make the bus 1 arrive evenly more easily.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment. For example, the shape and dimensions of each part are not limited to the above examples. The width W1 and the detection width W2 of the reference line 4 may be appropriately set according to the target width between the bus 1 and the stop 2. Further, the reference line 4 may be provided at an arbitrary position of the stop 2. For example, the reference line 4 may be provided on the upper surface 2 a of the stop 2 at a predetermined distance from the boundary between the upper surface 2 a and the step surface 2 b. . Further, the detection positions P1 and P2 may not be arranged in the width direction D1, and similarly, the detection positions P3 and P4 may not be arranged in the width direction D1. Further, the detection position P1 and the detection position P3 may not be separated from each other by the wheel base WB or more.

  Moreover, the 1st-4th sensors 11-14 should just be able to detect the reference line 4 in a predetermined position, and may be sensors other than an infrared sensor. Moreover, the camera 15 should just be able to image the predetermined range containing the one side surface 1a, for example, may be a camera which has a sensitivity to visible light. The bus 1 may not include the steering control unit 16 that controls the steering of the bus 1. For example, the driver steers the bus 1 based on the detection results of the first to fourth sensors 11 to 14. Also good. The bus 1 may not include the camera 15, and after the bus 1 has traveled along the reference line 4 to some extent by the driver's steering, the first to fourth sensors 11 to 14 as described above. The bus 1 may be run without leaving a gap of a predetermined width or more between the bus 1 and the stop 2 by the steering control based on the detection result. Further, when the road is right-hand traffic, the first to fourth sensors 11 to 14 may be arranged on the right side surface of the bus 1.

DESCRIPTION OF SYMBOLS 1 ... Bus, 1a ... One side surface, 2 ... Stop, 4 ... Baseline, 11 ... 1st sensor, 12 ... 2nd sensor, 13 ... 3rd sensor, 14 ... 4th sensor, 15 ... Camera (imaging part), 16: Steering control unit, 20: Image, D1: Width direction, D2: Front-rear direction, P1: Detection position of first sensor, P2: Detection position of second sensor, P3: Detection position of third sensor, P4: First Detection position of 4 sensors, W1... Width of reference line, W2... Detection width, WB.

Claims (5)

A bus that runs along a reference line provided at a stop,
The first to fourth sensors that are arranged on one side surface of the bus in the width direction and detect the reference line on the one side surface side of the bus,
The detection position of the first sensor is separated from the detection position of the second sensor by a detection width on the side opposite to the bus in the width direction,
The detection position of the third sensor is aligned with the detection position of the first sensor in the front-rear direction of the bus, and is separated from the detection position of the fourth sensor by the detection width on the opposite side of the bus in the width direction. And
The detection width is a bus wider than the width of the reference line.   2. The bus according to claim 1, wherein the detection position of the first sensor and the detection position of the third sensor are separated from each other by at least the wheel base of the bus in the front-rear direction.   The bus according to claim 1, wherein the first to fourth sensors are infrared sensors. A steering control unit that controls steering of the bus based on detection results of the first to fourth sensors;
The steering control unit, when the bus is traveling along the reference line, the reference line is located between the detection position of the first sensor and the detection position of the second sensor, and 4. The bus according to claim 1, wherein steering of the bus is controlled such that the reference line is positioned between a detection position of a third sensor and a detection position of the fourth sensor. An imaging unit that is attached to the bus and images a predetermined range including the one side surface;
The steering control unit controls steering of the bus so that the bus travels along the reference line based on the position of the one side surface and the position of the reference line in the image captured by the imaging unit. The bus according to claim 4.

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