JP2022147743A - Vehicle combination system - Google Patents

Abstract

To achieve the function of safely and automatically combining even vehicles without inter-vehicle communication means to each other, by using only a device mounted on a combining vehicle side.SOLUTION: In a vehicle combination system for coupling a vehicle to be combined and a combining vehicle via coupling means of each vehicle, the combining vehicle includes: a travel control device; a speed calculation device; a distance measurement device for measuring a distance to the vehicle to be combined; a coupler shape detection device for detecting a coupler shape; a combination ability determination device; and a combination management device for calculating a travel plan for reaching a target speed at the time of combination, from distance information and a current travel speed. When the combination ability determination means determines that the combining vehicle and the vehicle to be combined are in a state of having the ability of combination, the combination management device transmits the travel plan to the travel control device, and the travel control device controls the travel of the combining vehicle so that the received travel plan is followed.SELECTED DRAWING: Figure 1

Description

The present invention relates to vehicle merging systems.

In the merging work of trains, it is necessary to approach and merge trains at low speed without signals, so careful operation is required and the burden on drivers is high. Therefore, there is a demand for a device that guarantees safety in place of humans and automatically merges.
In Patent Document 1, when a merging vehicle receives a merging preparation completion signal output from a merging vehicle via a wireless transmission device when performing merging work, a millimeter-wave wireless transmission device and a merging support device calculate It is described that a speed pattern is calculated based on the remaining travel distance, and the merging is performed by traveling according to the speed pattern.
In addition, by transmitting the video captured by the camera installed in the merging vehicle to the monitor installed in the driver's seat of the merging vehicle, the driver of the merging vehicle can confirm the cover condition of the coupler of the vehicle and confirm safety. describes how to do it.

JP 2011-254666 A

The invention described in Patent Document 1 assumes that not only the merging vehicle but also the merging vehicle is equipped with a wireless transmission device. For this reason, no consideration has been given to dealing with merged vehicles that do not have a radio transmission device. Also, when a person visually confirms the direction of the coupler from the image on the monitor, it is difficult to judge a slight bend in the coupler. Nevertheless, if the merging operation is performed, there is a risk of causing the vehicle to break down.
SUMMARY OF THE INVENTION It is an object of the present invention to provide a vehicle merging system capable of safely merging trains that do not have inter-vehicle communication functions without human supervision and operation.

One representative vehicle merging system of the present invention is a vehicle merging system comprising a speed calculating device, a distance measuring device, a coupler shape detecting device, a merging possibility determining device, and a merging management device. The speed calculating device calculates the running speed of the merged vehicle, the distance measuring device calculates distance information between the merged vehicle and the merged vehicle, and the coupler shape detection device measures the merged vehicle and the merged vehicle. The state of the coupler of the vehicle to be merged is detected, and the merging possibility determination device determines whether or not the vehicle to be merged and the vehicle to be merged are in a state in which they can be merged based on the detection result of the coupler shape detection device. The merging management device calculates a travel plan from the distance information and the travel speed when the merging possibility determining device determines that the merging is possible.

According to the present invention, it is possible to provide a vehicle merging system capable of safely merging trains that do not have an inter-vehicle communication function without human supervision and operation.
Problems, configurations, and effects other than those described above will be clarified by the following description of the embodiments.

Diagram showing the block configuration of the vehicle combination system A diagram showing an example of the processing flow of the merger management device 125 A diagram showing an example of a merge start condition A diagram showing an example of a processing flow of distance information normality determination processing A diagram showing an example of travel plan creation processing in the merge management device 125 A diagram showing an example of a travel plan in the combined management device 125 A diagram showing an example of a processing flow of the merging possibility determination device 124 FIG. 4 is a diagram showing an example of detection of the orientation of the coupler in the coupler shape detection device 122; A diagram showing an example of distance detection between couplers in the distance measuring device 123

In this embodiment, referring to FIGS. 1 to 9, a vehicle that performs connection control for connecting a merging vehicle 101 running as separate trains and a merging vehicle 102 running behind it by a coupler. A first embodiment of a merging system is described.
Also, in this embodiment, a one-car train set will be described as an example for both the merged car 101 and the merged car 102, but the present invention can also be applied to a train train composed of two or more cars. This also applies to other embodiments.
Furthermore, in this embodiment, an embodiment will be described in which the merging vehicle 102 advances and is connected to the merging vehicle, but the present invention is not limited to the case where the merging vehicle 102 moves forward. It can also be applied to the case where the merging vehicle 102 is positioned behind the merging vehicle 102 and connected to the merging vehicle 101 by retreating. This also applies to other embodiments.

(Block configuration)
FIG. 1 shows the configuration of the vehicle combination system of this embodiment. The merging vehicle 101 has a coupler 111 on its back. The merging vehicle 102 is equipped with a coupler 121, a coupler shape detecting device 122, and a distance measuring device 123 on the front, and furthermore, a merging possibility determining device 124 for performing the merging, a merging management device 125, and a running control device. 126 and a speed sensor 127 .

The coupler 111 and the coupler 121 are devices that couple vehicles by bringing their parts into contact with each other. Henceforth, the surface which couplers contact each other is called a connection surface.
The coupler shape detection device 122 is installed at a position where the shapes of the coupler 111 and the coupler 121 can be measured, and outputs the measurement result of each coupler shape to the mergeability determination device 124 . The coupler shape detection device 122 can be a camera, a distance image sensor, an optical ranging sensor (LiDAR: Light Detection and Ranging, hereinafter referred to as lidar) capable of acquiring two-dimensional or three-dimensional point group information, or the like. Image information in the case of a camera, point cloud information in the case of a lidar, and either image information and point cloud information in the case of a range image sensor are output to the merging possibility determination device 124 .

Any number of devices may be installed as long as the couplings of both the merging vehicle 101 and the merging vehicle 102 can be measured. Alternatively, separate sensors may be combined, such as installing a camera as a sensor for measuring one coupler and installing a lidar as a sensor for measuring the other coupler. Hereinafter, an example in which two cameras are mounted as the coupler shape detection device 122 will be described.

The distance measuring device 123 calculates the distance from the connecting surface of the coupler 121 of the merging vehicle 102 to the connecting surface of the coupler 111 of the merging vehicle 101 and outputs it to the merging management device 125 as distance information. Details of the distance calculation method will be described later. The distance measuring device 123 may be of any type as long as it can measure a distance without contact, such as a distance measuring sensor such as a laser radar, an ultrasonic sensor, an infrared sensor, a stereo camera, or a lidar.
Further, if distance information can be obtained by the connector shape detection device 122 , the connector shape detection device 122 may be used as the distance measurement device 123 . For example, when using a distance image sensor such as TOF, or when storing the size of the coupler in advance and measuring the distance from the image of the coupler captured by the camera, the coupler shape detection device can be used as a distance measuring device. can be used as
Hereinafter, a case where a laser radar is used as the distance measuring device 123 will be described as an example.

The merging possibility determination device 124 receives the coupler shape information from the coupler shape detecting device 122, determines whether or not the vehicle 101 to be merged and the vehicle 102 to be merged can be merged by a merging possibility determination process, and determines that the merging is possible. If so, the value of the merging possibility determination flag is set to 1; Details of the merging possibility determination process will be described later.

The merging management device 125 receives the merging possibility determination flag from the merging possibility determining device 124, the current speed of the merging vehicle 102 from the speed sensor 127, the distance information from the distance measuring device 123, and the merging possibility determination flag. Triggered by the value being 1, a travel plan is calculated and output to the travel control device 126 . The travel plan is a plan for controlling the speed of the vehicle in accordance with the distance to the coupling surface of the coupler 111 of the merged vehicle 101. For example, a configuration in which a target speed is specified for each travel position, a driving operation ( (acceleration, deceleration, coasting, etc.) may be specified.

The travel control device 126 receives the travel plan from the merge management device 125, inputs the current speed from the speed sensor 127, and controls the travel speed of the merge vehicle 102 so as to follow the travel plan. The travel control device 126 may adopt any control method as long as it can control the travel of the merge vehicle 102 so as to follow the travel plan. For example, the vehicle may be controlled by calculating the braking/driving force so as to achieve the target position and speed, or the notch may be proportionally controlled so as to follow the target speed.

The speed sensor 127 calculates the speed of the merged vehicle and outputs it to the merged management device 125 and the travel control device 126 . Any type of speed sensor can be used as long as it can calculate the speed of the merging vehicle. For example, it may be a configuration that calculates the speed from the wheel diameter and the wheel rotation speed, a configuration that integrates the acceleration detected by the acceleration sensor to calculate the speed, and a position information acquired from GNSS (Global Navigation Satellite System) is time-differentiated. It may be configured to be calculated by

(Operation of merger management device 125)
FIG. 2 shows the processing flow of the merging management device 125 .
<Step 1010>
At step 1010, it is determined whether or not the merging start condition is satisfied. Details of the merging start condition will be described later.
<Step 1020>
The step 1020 outputs a merge control start signal to the merge possibility determination device 124 and proceeds to step 1030 .
<Step 1030>
A step 1030 receives a mergeability determination flag from the mergeability determination device 124 and determines whether or not the value of the flag is 1. If Yes, the process proceeds to a step 1040 .
<Step 1031>
A step 1031 performs unmergeable processing and terminates the processing. Details of the unmergeable processing will be described later.
<Step 1040>
A step 1040 acquires the distance information between the couplers from the distance measuring device 123 , executes a distance information normality determination process, and proceeds to a step 1050 . The details of the distance information normality determination process will be described later.
<Step 1050>
A step 1050 decides whether or not the value of the distance information normal flag is 1. If Yes, the process proceeds to a step 1060 , and if No, the process proceeds to a step 1051 .
<Step 1051>
A step 1051 carries out an abnormality process and terminates the process. Details of the error processing will be described later.
<Step 1060>
At step 1060, it is determined whether or not the value of the travel plan creation completion flag is 1. If Yes, the process proceeds to step 1070, and if No, the process proceeds to step 1090.
<Step 1070>
A step 1070 carries out a travel plan creation process and proceeds to a step 1080 . Details of the travel plan creation process and the created travel plan will be described later.
<Step 1080>
A step 1080 decides whether or not the value of the travel plan creation completion flag is 1. If Yes, the process proceeds to a step 1090 , and if No, the process proceeds to a step 1051 .
<Step 1090>
A step 1090 outputs the created travel plan and the distance information input from the distance measuring device 123 to the travel control device 126, and proceeds to step 1100. FIG.
<Step 1100>
A step 1100 confirms whether or not a merge completion condition has been established, and if Yes, the process is terminated, and if No, the process returns to the step 1040 . If the process returns to step 1040, the processes from step 1040 to step 1100 are repeated until the merging completion condition is satisfied in step 1100. FIG. Details of the merge completion conditions will be described later.

(Merge start condition)
An example of the merging start condition will be described with reference to FIG.
As a merging start condition, for example, as shown in FIG. The details of how to determine the merge control start position will be described later.
As a method for detecting that the merge vehicle 102 has reached the merge control start position, the merge control start position is stored in advance in the merge vehicle 102, and the current position of the merge vehicle 102 reaches the stored merge control start position. There are various means such as a method of detecting such a situation, a method of installing a transmission device that transmits a signal instructing the start of merging control in advance on the running road, and a method of detecting that the merging control device 125 has received the signal. included. In addition, the method of acquiring the current position of the merging vehicle 102 includes various means such as a method of calculating from the wheel diameter and wheel rotation speed, and a method of acquiring from GNSS (Global Navigation Satellite System). .

Details of the method for determining the merge control start position will be described below. The merge control start position is determined from the position of the coupler 111 of the vehicle to be merged 101 using the distance threshold and speed threshold determined so that the coupler shape detection device 122 can reliably detect the coupler of each vehicle. Set the deceleration start position where the current speed can be safely decelerated to the speed threshold up to the position where the distance threshold is subtracted.
The distance threshold is shorter than the maximum detectable distance of the coupler shape detection device 122 and is a distance with a margin sufficient to detect the coupler 111 of the merged vehicle 101 . The margin is based on the environmental conditions for merging (with or without a roof, whether the road is straight or curved, etc.) and the performance of the coupler shape detection device 122 to be mounted (detection distance, detection accuracy, resolution, measurement cycle). It is determined so that the coupling 111 of the merged vehicle 101 can be reliably measured.
In addition, the speed threshold is set at a speed lower than the intersection of the brake pattern of the normal maximum brake set (drawn) with the maximum speed as the starting point and the distance threshold so that the speed is 0 at the coupler position of the merged vehicle 101. and the coupler shape detection device 122 can measure the coupler 111 of the to-be-merged vehicle 101 and the coupler 121 of the merging vehicle 102 multiple times while the merging vehicle 102 travels the distance of the distance threshold. It is the set speed.

In addition to the method shown in FIG. 3, the method of determining the merge control start position may be a method that triggers detection of the coupler of the merging vehicle 101 by the coupler shape detection device 122, or a method that uses distance Various means are included, such as a method that triggers when the measuring device 123 approaches the merged vehicle 101 within a certain distance.
Furthermore, a method may be used in which the driver presses a switch at an arbitrary timing as a trigger. In this case, if the coupler shape detection device 122 can measure the coupler 111 of the merged vehicle 101, the control is started as it is. It is possible to think of a method to ensure safety by

(Conditions for completion of merger)
As a merging completion condition, for example, there is a method of triggering that the inter-coupler distance acquired by the distance measuring device 123 has become equal to or less than a predetermined value. In addition, in a vehicle in which an electric circuit and an air pipe are also connected when the vehicle is connected, it is possible to receive an electric signal from the merged vehicle 101 via the coupler 121 and detect a pressure change in the air pipe. may be used as a trigger.

(Distance information normal judgment processing)
Details of the distance information normality determination process will be described using the process flow of FIG.
<Step 2010>
A step 2010 inputs distance information from the distance measuring device 123 and proceeds to a step 2020 .
<Step 2020>
A step 2020 confirms whether or not the distance information normal flag is 0. If Yes, the process proceeds to a step 2030, and if No, the process ends.
<Step 2030>
Step 2030 performs standby processing and proceeds to step 2040 . Details of the standby process will be described later.
<Step 2040>
A step 2040 inputs distance information from the distance measuring device 123 and proceeds to a step 2050 .
<Step 2050>
In step 2050, distance normality determination is performed, and if Yes, the process proceeds to step 2060, and if No, the process proceeds to step 2061. The details of the distance normality determination will be described later.
<Step 2060>
A step 2060 sets the distance information normal flag to 1 and terminates the process.
<Step 2061>
A step 2061 sets the distance information normal flag to 0, and terminates the process.

Next, the details of the standby process will be described. In the standby process, the current speed V1 is input from the speed sensor ₁₂₇ , and the transition to the _next step is waited for the standby time _tS seconds calculated by the following formula from the current speed V1 and the error threshold _dL .
t _S =d _L /V ₁
Here, the error threshold is an arbitrary value larger than d, where d is the measurement error assumed based on the specifications of the sensor.

Next, the details of the normal distance determination will be described. The normal distance determination is calculated from the movement distance calculated from the difference between the distance received at step 2010 and the distance received at step 2030, the current speed obtained from the speed sensor 127, and the processing time from step 2010 to step 2030. It is determined whether or not the moving distance is smaller than the error threshold _dL . The initial value of the distance information normal flag is 0.

(Travel plan creation process and travel plan)
Details of the travel plan creation process and the travel plan will be described with reference to FIGS. 5 to 7. FIG. By minimizing the amount of coasting, the travel plan is created so as to reduce the influence of the difference in deceleration during coasting due to the number of passengers and road surface conditions, and to shorten the time required for merging.
A specific creation example is shown in FIG. 5A. First, a coasting run curve (hereinafter referred to as a coasting run curve) is created such that the speed becomes V _M [km/h] at the connecting surface position 0 [m] of the coupler 111 of the merged vehicle 101 . Velocity _VM is set with reference to the speed at the time of manual merging so that the impact at the time of collision is as small as possible. Subsequently, a run curve for constant speed running at a speed V _C [km/h] (hereinafter referred to as a constant speed run curve) is created. The speed _VC is set to the lowest speed at which the merging vehicle 102 can stably run at a constant speed. Finally, a run curve (hereinafter referred to as a deceleration run curve) for decelerating from the current speed V1 to a speed of ₀ [km/h] at a predetermined deceleration is created.

Then, the deceleration run curve is adopted until the intersection of the deceleration run curve and the constant speed run curve, the constant speed run curve is adopted until the intersection of the constant speed run curve and the coasting run curve, and the coasting run curve is adopted thereafter to create a planned run curve to be finally output. . However, as shown in FIG. 5B, when the distance L _C between the couplers at the intersection of the deceleration run curve and the constant speed run curve is smaller than the distance L _D between the couplers at the intersection of the constant speed run curve and the coasting run curve, the deceleration run curve and the coasting run curve A deceleration run curve is adopted up to the intersection of , and a coasting run curve is adopted thereafter to create a planned run curve to be finally output.
At this time, if the intersection of the deceleration run curve and the coasting run curve does not exist, the preparation of the travel plan is stopped. The value of the travel plan creation completion flag is set to 1 when the creation of the travel plan is completed, and the value of the travel plan creation completion flag is set to 0 when the creation of the travel plan is cancelled. The initial value of the travel plan preparation completion flag is zero.
From the above, it is possible to create a travel plan that does not include a stop motion until merging. FIG. 6 shows an example of the travel plan created as described above.

(Processing that cannot be merged)
Next, the details of the unmergeable process will be described. In the merging impossibility process, the merging management device 125 notifies the operation management system or the like that merging is impossible if there is no driver or driver in driverless driving or the like, using a notification means (not shown). do. The details of the notification means will be described later. Furthermore, the merging management device 125 creates a travel plan from the current position to a safe stop and transmits it to the travel control device 126 .
Notification means include a method of displaying on the screen of the cab, a method of lighting a specific indicator light, voice guidance, etc. If there is no driver or driverless driving, the operation management system etc. will not be connected. Any method may be used as long as it can recognize the possible state.

(abnormal processing)
Next, the details of the abnormality processing will be described. In the abnormality processing, even if the merging management device 125 determines that the coupler is ready for merging by the merging possibility determination processing in the merging possibility determination device 124, if there is any other abnormality, the driver or , when there is no driver due to driverless driving or the like, the operation management system or the like is notified that automatic merging is impossible.
Specifically, when the distance information is abnormal or when the preparation of the travel plan cannot be completed, it is notified that the automatic merging is impossible. The notification means is the same as in the unmergeable process. Also, the merging management device 125 creates a travel plan from the current position to a safe stop and transmits it to the travel control device 126 .

(Operation of Merge Possibility Determining Device 124)
Details of the processing in the merging possibility determination device 124 will be described using the processing flow of FIG.
<Step 3010>
A step 3010 determines whether or not a merge control start signal has been received from the merge management device 125 . If yes, go to step 3020 . If No, the process ends.
<Step 3020>
A step 3020 inputs the shape information of the coupler 111 and the coupler 121 from the coupler shape detector 122 , and proceeds to step 3030 .
<Step 3030>
A step 3030 performs a merging possibility determination process, and proceeds to a step 3040 . Details of the merging possibility determination process will be described later.
<Step 3040>
A step 3040 sends a merge possibility determination flag to the merge management device 125, and terminates the process.

(Merge possibility determination process)
Details of the merging possibility determination process will be described with reference to FIG. In the merge possibility determination process, it is determined that the coupler 111 of the vehicle to be merged 101 and the coupler 121 of the merging vehicle 102 are couplers that can be merged, and that both couplers are in a mergeable state. Therefore, the following three determinations are made.
<Judgment 1>
Determination 1: The coupler 111 of the vehicle to be merged 101 and the coupler 121 of the merged vehicle 102 are of types that can be merged.
<Judgment 2>
Determination 2: The coupler covers of the coupler 111 of the merging vehicle 101 and the coupler 121 of the merging vehicle 102 are open.
<Judgment 3>
Determination 3: The coupler 111 of the vehicle to be merged 101 and the coupler 121 of the merged vehicle 102 are oriented so that they can be merged.
The merging possibility determination device 124 sets the value of the merging possibility determination flag to 1 only when it is determined that merging is possible in all of the above three determinations, and sets the value of the merging possibility determination flag to 0 in other cases. The details of each determination process will be described below.

(Processing of judgment 1)
First, details of the processing of determination 1 will be described. First, the merging possibility determination device 124 preliminarily stores images of all couplers that can be merged by the coupler 121 of the merging vehicle 102 as standard images. This standard image is preferably an image captured by camera 1 . Next, by comparing the image of the coupler 111 of the vehicle to be merged 101 acquired from the coupler shape detection device 122 with the standard image, it is determined whether the coupler 111 of the vehicle to be merged 101 is a device that can be merged. determine whether
As a collation/judgment method, a known image processing means, for example, a feature point extraction method such as SIFT (Scale-Invariant Feature Transform) or SURF (Speed Up Robust Features) is used to extract the feature amount of the coupler portion in each image, A method of comparing whether they match using matching methods such as SSD (Sum of Squared Differences) and NCC (Normalized Cross Correlation), and a known deep learning method CNN (Convolutional Neural Network) etc. Various methods can be applied, such as a method of learning and judging images of couplers that can be merged.

(Processing of judgment 2)
Next, the details of the processing of determination 2 will be described. Determination 2 uses the deep learning method used in determination 1 and known region division techniques, such as the region expansion method and the watershed method, to extract the vehicle to be merged from the image acquired from the coupler shape detection device 122. 101 and the area of the coupler 111 of 101 of the merged vehicle are extracted respectively. If the coupler 111 is not detected although the vehicle to be merged 101 is detected, it is determined that the coupler cover of the vehicle to be merged is closed, and the coupler 111 of the vehicle to be merged 101 is not detected. If so, it is determined that the coupler cover is open.

(Processing of judgment 3)
Details of the processing of determination 3 will be described with reference to FIG. In FIG. 8, the y-coordinate is the forward direction of the car body, the x-coordinate is the sleeper direction, and the reference coordinate system is a coordinate system whose origin is the lens position of the camera 1 installed facing the forward direction.
_First , a method of calculating the orientation θ2 of the coupler 111 of the merged vehicle 101 will be described. The merging possibility determination device 124 sets θ ₂ ′ as the orientation of the coupler 111 when the standard image of the coupler 111 used in the determination 1 is taken, and stores this. The amount of displacement Δθ ₂ from the standard image θ ₂ ′ is calculated from the rotation matrix of the image calculated when the matching method is used in judgment 1 and the characteristic information (focal length, number of pixels, etc.) of the camera being used. calculate. A value obtained by adding this displacement amount Δθ ₂ to θ ₂ ′ of the standard image is calculated as the current orientation θ ₂ of the coupler 111 . Alternatively, it can be similarly calculated by a method using a known background difference.
Next, _a method of calculating the orientation θ1 of the coupler 121 of the merge car 102 will be described. In the camera 2 of FIG. 8, an image obtained when θ1 of the coupler 121 of the merging vehicle ₁₀₂ is 90° is stored in advance in the merging possibility determination device 124 as a right-angle image. Then, the displacement amount Δθ ₁ is calculated for the current image of the coupler 121 captured by the camera 2 by using the same method as the calculation of θ ₂ described above. Then, a value obtained by adding this displacement amount to ₉₀ ° is calculated as θ1.

If θ ₁ and θ ₂ obtained from these are within the allowable angular error from 90°, it is determined that merging is possible. If either one exceeds the allowable value, it is determined that merging is impossible. The allowable angular error is the angular error pre-defined by the coupler that can be merged. The calculation means for the above θ ₁ and θ ₂ uses the lens position of the camera 1 as the reference coordinate system, and the case where the camera 2 is moved in parallel with respect to the camera 1 in the x direction is explained as an example. The reference coordinate system may be set at any position as long as the installation position and angle of each camera can be calculated.
The above three determination methods, determination 1, determination 2, and determination 3, have been described as an example when the coupler shape detection device 122 is a camera. The shape information of the car body and couplers that can be merged can be stored in advance as point group information, and a similar determination can be made by using a known point group matching method such as ICP (Iterative Closest Point).

(Operation of distance measuring device 123)
An example of the operation of the distance measuring device 123 will be described with reference to FIG. The distance measuring device ₁₂₃ calculates the distance L1 from the connecting surface of the coupler 121 of the merging vehicle 102 to the connecting surface of the coupler 111 of the merging vehicle 101 . The reference coordinate system in FIG. 9 is similar to that described in FIG. _The distance L1 is calculated by the following formula.
L ₁ =L ₀ -L ₂
Here, the distance _L0 is the distance measured by the laser radar from the measurement origin of the laser radar to the connecting surface of the coupler 111 of the vehicle 101 to be merged. _The distance L2 is the distance from the measurement origin of the laser radar to the connecting surface of the coupler 121 of the merging car 102 when the orientation θ1 of the coupler 121 of the merging car ₁₀₂ is 90°. It can be calculated in advance from the installation position of each device. If the value of either or both of θ ₁ and θ ₂ calculated in the merging possibility determination process is not 90°, the distance at which the two connecting surfaces actually start contacting and L ₁ calculated by the above formula is An error occurs. However, since the width (length in the x direction) of the connecting surface of the coupler mounted on the train is generally about several tens of centimeters, the value of both or either of θ ₁ and θ ₂ is 90°. If not, the error is considered to be several centimeters to ten and several centimeters. Since an error of this degree has a very small effect on the speed change during coasting immediately before merging, it can be ignored in this embodiment. However, if the width of the connecting surface is large and the value of this error is also large, the error is geometrically corrected from the information on the installation position of the distance measuring device 123 and the θ ₁ and θ ₂ calculated in the merging possibility determination process. It will be done.
In the above operation example, a laser radar is used as the distance measuring device 123, but the distance L0 can be similarly calculated by obtaining the distance _L0 in a non-contact manner even when other sensors are used.

(Operation of travel control device 126)
Next, the details of the operation of the travel control device 126 will be described. The travel control device 126 inputs the distance information between the couplers and the travel plan from the combined management device 125 and inputs the current speed from the speed sensor 127 . The travel control device 126 refers to the travel plan based on the input distance information between the couplers, and calculates the corresponding target speed and driving operation information. If the calculated driving operation is deceleration or constant speed, the current speed and target speed are compared, the braking/driving force that can follow the target speed is calculated, and the command value for the braking/driving force is sent to the drive device (not shown). do. When the driving operation is coasting, a coasting command is transmitted to the driving device to coast the vehicle.

When the speed sensor 127 uses a sensor with low speed accuracy in a low speed range, such as a tachometer, the travel control device 126 uses the current speed input from the speed sensor 127 to maintain control accuracy. If it is equal to or higher than VC in 5A or FIG. 5B, it is adopted as the current speed of the vehicle as it is, and if it is less than _VC , the speed _VC calculated by the following _formula may be adopted as the current speed of the vehicle.
VC = _ΔL /ΔT
Here, ΔL is the moving distance calculated from the difference between the distance information of one cycle before and the current distance information, and ΔT is the processing time (time of one cycle) therebetween.
If a sensor capable of accurately obtaining the speed over the entire speed range is used as the speed sensor 127, the speed obtained from the speed sensor 127 may be used as the current speed.

(Effect)
According to the first embodiment described above, the merging vehicle 102 recognizes the positional relationship between the vehicles and automatically stops until the merging is completed, even if the merging vehicle 101 does not have communication means with the merging vehicle 102. It is possible to merge without In addition, it has a function to determine whether the coupler can be merged by detecting the shape of the coupler, and an abnormality detection function when measuring the distance between the couplers. It has a function of controlling to stop the merging vehicle 102 in front of the merging vehicle 101 at the time of detection. From the above, it is possible to realize a system capable of merging vehicles safely and in a short time.

In addition, the present invention is not limited to the above-described embodiments, and includes various modifications. For example, the above-described embodiments have been described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations.
For example, the vehicle combination system of the present disclosure can be applied to transportation robots in factories, cargo container transportation vehicles in airports, and other moving bodies that may be connected and run in addition to railway vehicles. be. Other aspects conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.
In addition, it is possible to replace part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Moreover, it is possible to add, delete, or replace a part of the configuration of each embodiment with another configuration.
For example, the merging management device, the coupler shape detection device, and the merging possibility determination device that the merging car has are not necessarily installed in the merging car, but are provided outside the merging car in a state that can be connected to the merging car. may These devices may be installed on the ground, may be installed on robots or the like near the merging vehicle and the merging vehicle, or may be provided on the cloud.
Further, each of the above configurations, functions, processing units, processing means, and the like may be realized by hardware, for example, by designing a part or all of them using an integrated circuit. Moreover, each of the above configurations, functions, etc. may be realized by software by a processor interpreting and executing a program for realizing each function. Information such as programs, tables, and files that implement each function can be stored in recording devices such as memories, hard disks, SSDs (Solid State Drives), or recording media such as IC cards, SD cards, and DVDs.

101... Vehicle to be merged, 102... Vehicle to be merged, 111... Coupler of vehicle to be merged, 121... Coupler of vehicle to be merged, 122... Coupler shape detection device, 123... Distance measuring device, 124... Merge possibility determination device, 125 ... merged management device, 126 ... traveling control device, 127 ... speed sensor

Claims (7)

In a vehicle merging system comprising a speed calculating device, a distance measuring device, a coupler shape detecting device, a merging possibility determining device, and a merging management device,
The speed calculation device calculates the running speed of the merged vehicle,
The distance measuring device calculates distance information between the merged vehicle and the merged vehicle,
The coupler shape detection device detects the state of couplers of the merging vehicle and the merging vehicle,
The merging possibility determination device determines whether or not the merging vehicle and the to-be-merged vehicle are in a merging state based on the detection result of the coupler shape detection device,
The vehicle merging system, wherein the merging management device calculates a travel plan from the distance information and the travel speed when the merging possibility determining device determines that the merging is possible. The vehicle merging system according to claim 1,
The vehicle combination system has a cruise control device,
The travel control device controls travel of the merged vehicle based on the travel plan calculated by the merger management device, the distance between the merged vehicle and the merged vehicle, and the traveling speed of the merged vehicle. vehicle merging system. The vehicle merging system according to claim 1,
The vehicle merging system, wherein the coupler shape detection device is capable of acquiring at least one of image information and two-dimensional or three-dimensional point group information. The vehicle merging system according to claim 1,
The merging possibility determination device detects the open/closed state of the coupler covers of the couplers of both the merging vehicle and the merging vehicle based on the measurement results of the coupler shape detecting device, and A vehicle merging system, wherein it is determined that the merging vehicle and the to-be-merged vehicle are ready for merging when a coupler of the vehicles is exposed. The vehicle merging system according to claim 1,
The merging possibility determination device detects orientations of couplers in both the merging vehicle and the merging vehicle based on the measurement result of the coupler shape detection device, and determines whether the orientations of the couplers are mergeable. and determining that the merging vehicle and the to-be-merged vehicle are in a mergeable state when the two vehicles are in a state such that the vehicle is in a merging state. The vehicle merging system according to claim 1,
The merging possibility determination device stores in advance a coupler that can be merged with the coupler of the merging vehicle, compares the measurement result of the coupler shape detection device with the stored coupler, and determines whether the merging vehicle can be merged. A vehicle merging system, wherein when a coupler is a merging coupler, it is determined that the merging vehicle and the to-be-merged vehicle are in a mergeable state. The vehicle merging system according to claim 1,
The vehicle coupling system, wherein the coupler shape detection device also serves as the distance measurement device.

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