KR102504548B1 - 3d shape data acquisition method for automatic car wash equipment and vehicle shape data acquisition system - Google Patents

Abstract

The present invention relates to a method capable of reducing installation costs required for obtaining vehicle shape data while obtaining precise shapes up to inclined portions of the front and rear surfaces of a vehicle entering an automatic car wash system.
The method according to the present invention uses a first 2D lidar disposed at a predetermined distance from the upper surface of the car body in a lateral direction from a center line along the longitudinal direction of the car body, to detect at least the upper surface of the car body. Obtaining shape data of the vehicle body by scanning between a location including the center and the side of the vehicle body, and measuring the width of the vehicle body using a distance sensor disposed at a predetermined height from the ground at a predetermined distance from one side of the vehicle body. and obtaining overall shape data of the vehicle body by mirroring data of the first 2D lidar using the measured intermediate distance of the width of the vehicle body.

Description

3D shape data acquisition method of vehicle for automatic car wash device and vehicle 3D shape data acquisition system therefor

The present invention relates to a method for acquiring vehicle shape data for an automatic car wash and a system for obtaining vehicle shape data used in the method. More specifically, the present invention relates to a method capable of acquiring shape information precise enough to increase the efficiency of automatic car washing and to automate steam car washing at low cost, and to a device used in the method.

A conventional automatic car wash device uses a simple one-dimensional sensing device such as a beam sensor or an ultrasonic sensor to roughly recognize the length, width, and position of a vehicle that has entered the car wash device, and then sprays water or cleaning fluid and brushes, etc. is rotated to remove contaminants, and a drying means such as a blower is used to remove moisture from the surface of the vehicle during the car washing process.

Since the recognition accuracy of the car shape or position obtained through a simple sensing device such as a beam sensor or an ultrasonic sensor in such a conventional automatic car washing device is low, interference or collision between the washing module or drying module operated for automatic car washing and the car In order to prevent the car from being damaged by the washing module or the drying module, it has been operated so that the devices are operated at a relatively safe separation distance from the car.

For this reason, general automatic car wash devices increase the cleaning power by spraying water or cleaning liquid at high pressure, but the cleaning power is not sufficient, so the car wash is performed using a means that physically wipes the surface of the car, such as a brush. At this time, the distance between the brush and the exterior of the vehicle If is farther than a certain distance level, there is a non-cleaning section, and if it is too closely adhered to, damage to the attachment attached to the vehicle occurs. In addition, since the operation of removing water through blowing is also performed at a considerable distance, there is a problem in that water attached to the vehicle is not sufficiently removed.

In addition, in an automatic car wash machine, a brush or a drying device must adhere to the contour of a vehicle as much as possible, but accurate data on the contour of a car to be washed cannot be obtained. Manpower for induction is essential, which causes an increase in maintenance costs of automatic car wash machines.

On the other hand, if multiple 2D lidars are used instead of ultrasonic sensors or beam sensors, it is possible to precisely obtain the shape data of the car being washed, so that the brush or drying means can be applied to the car without aligning the car to the automatic car washer. Even if it operates closely to the contour of the machine, it is desirable to minimize damage to the paintwork, but since a large number of expensive 2D lidars must be installed, the installation cost of the automatic car wash is significantly increased and the economic efficiency is poor.

In addition, the steam car wash method is an environmentally friendly method because it is efficient in removing contaminants attached to the vehicle and can use only a small amount of water. It is difficult to apply the same method, so only manual work by manpower is being carried out.

Publication No. 2011-0107629

An object of the present invention is a method for acquiring vehicle shape data for an automatic car wash device capable of acquiring three-dimensional precise shape data of a vehicle required for close cleaning of the automatic car wash device and reducing installation costs required for acquiring the vehicle shape data. and a vehicle shape data acquisition device for an automatic car wash used in this method.

A first aspect of the present invention for solving the above problems uses a first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body in the lateral direction. Thus, obtaining shape data of the vehicle body by scanning between a position including at least the center portion of the upper surface of the vehicle body and the side surface of the vehicle body, and a distance sensor disposed at a predetermined height from the ground at a predetermined distance from one side of the vehicle body measuring the width of the vehicle body using a device, and obtaining overall shape data of the vehicle body by mirroring data of the first 2D lidar using the intermediate distance of the measured vehicle body width, A method for acquiring vehicle shape data for a car washing device is provided.

The distance sensor may preferably be a beam sensor or a 1D lidar.

According to this method, the distance sensor is arranged on one side of the car wash to obtain the vehicle width and alignment angle data of the car wash, and mirroring is performed based on the data obtained from the upper 2D LIDAR sensor and the vehicle width data obtained from the side distance sensor. It can be configured to obtain vehicle shape data. Although this configuration is somewhat insufficient to generate accurate external appearance data for the side of the vehicle, it is not difficult to generate the shape data of the entire vehicle required for car washing, and it is a shape that can increase the efficiency of automatic car washing or steam car washing at a low cost. data can be obtained.

In addition, the precise data of the vehicle allows the washing brush or the drying blower to be operated as close to the surface of the vehicle as possible when the automatic car washing device is operated, thereby significantly improving the quality of the car washing. In particular, it is possible to automate car washes that require car washing in close contact with the vehicle surface, such as steam washing, to solve problems such as environmental pollution reduction through minimization of water usage and location limitation through minimization of car wash installation area and space. .

A second aspect of the present invention for solving the above problems uses a first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body in the lateral direction. obtaining shape data of the vehicle body by scanning between at least the center portion of the upper surface of the vehicle body and the side surface of the vehicle body; obtaining side shape data of the car body by scanning, using a 2D lidar, between at least a predetermined position on the ground or the ground and a side end of the car body, and the data of the first 2D lidar and the second 2D lidar An object of the present invention is to provide a method for acquiring vehicle shape data for an automatic car washing apparatus, comprising obtaining LIDAR data as overall shape data of a vehicle body.

According to this method, the first 2D lidar is placed on one side with respect to the center line parallel to the longitudinal direction of the car, and the second 2D lidar is placed on the side of the car to obtain shape data, respectively. , Since the shape data of the entire vehicle can be obtained through mirroring through the fact that the shape of the car body is symmetrical, it is possible to obtain precise shape information of the car, including accurate exterior data on the side of the vehicle, using only two 2D lidars. can be obtained at low cost.

In the second aspect, the second 2D lidar may be separated from one side of the vehicle body by a predetermined distance and positioned at a height higher than a door of the vehicle body.

Through this, the first 2D lidar can acquire more precise data about the shape of the upper surface of the vehicle and the boundary between the upper surface and the side surface.

In the first aspect or the second aspect, the scan of the first 2D lidar and the second 2D lidar in the car body length direction is such that the car is the first 2D lidar and the second 2D lidar. , or the cradle for holding the first 2D lidar and the second 2D lidar moves toward the stationary car, or passes the car and the first 2D lidar and the second 2D lidar. This can be achieved through moving the cradle toward each other.

In the first side or the second side, the first 2D lidar consists of two channels having two light sources, and the two light sources are spread at a predetermined angle along the length direction of the vehicle body, respectively, in the front and rear directions. It can emit light toward the side.

Through this, it is possible to increase the shape accuracy of the inclined portion with respect to the ground, such as the front and rear portions of the vehicle body. For example, precise shape data can be obtained even for the shape of a small structure that can become an obstacle in automatic car washing, such as an emblem provided on the front of a car body.

In the first aspect or the second aspect, light having a predetermined intensity or less among light reflected from the car body and received by the scanning of the first 2D lidar may be removed through a filter.

Through this, it is possible to significantly reduce noise for shape information generated when laser light emitted from the lidar is scattered by water droplets scattered from the car washing device or from the vehicle body.

A third aspect of the present invention for solving the above problems is a first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body, A distance sensor disposed at a predetermined height from the ground at a predetermined distance from one side and measuring the width of the vehicle body, and by processing the data generated by the first 2D lidar and the distance sensor, obtains an intermediate distance of the measured width of the vehicle body. It is to provide a car shape data acquisition device for an automatic car wash system, including a data processing device that performs a process of obtaining shape data of the entire car body by mirroring data of the first 2D lidar using the first 2D lidar.

Since the vehicle shape data acquisition apparatus according to the third aspect of the present invention can relatively accurately obtain vehicle shape data using only one 2D lidar, it is possible to obtain a precise vehicle shape that can be washed by steam at low cost.

A third aspect of the present invention for solving the above problems is a first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body, A second 2D lidar that measures the width of the car body, which is arranged at a predetermined height from the ground at a predetermined distance from one side, and fuses the data generated by the first 2D lidar and the data generated by the second 2D lidar. It is to provide a vehicle shape data acquisition device for an automatic car washing device, including a data processing device that performs a process of acquiring shape data of the entire vehicle body by performing a process of obtaining shape data of the entire vehicle body.

Since the vehicle shape data acquisition device according to the fourth aspect of the present invention uses two 2D lidars, the installation cost is increased compared to using one 2D lidar, but even the shape data of the side of the car can be accurately obtained, resulting in more precise The vehicle shape can be implemented at a relatively low cost.

In the third or fourth aspect, the first 2D lidar or the second 2D lidar is placed in contact with or is disposed at a predetermined distance away from the first 2D lidar or the second 2D lidar to prevent liquid droplets scattering from the car washing device or the vehicle body. An air curtain or an air blower may be provided to protect the 2D lidar or the second 2D lidar.

Through this, scattering of light by droplets scattering toward the first 2D lidar or the second 2D lidar can be suppressed, thereby increasing the accuracy of shape data and protecting expensive 2D lidar from contamination. there will be

In the third aspect or the fourth aspect, the first 2D lidar may include two channels having two light emitting sources.

Through this, it is possible to increase the shape accuracy of the inclined portion with respect to the ground, such as the front and rear portions of the vehicle body.

According to the present invention, vehicle shape data necessary for an automatic car wash device can be accurately obtained at low cost.

In addition, when the car shape data obtained according to the present invention is applied to an automatic car wash, since the precision of the car shape information (including location information) is very high, the precise data of the vehicle is useful for washing when the automatic car wash device is operated. By allowing the brush or drying blower to operate as close to the surface of the car as possible, it is possible to significantly improve the quality of car washing. In particular, it is possible to automate car washes that require car washing in close contact with the vehicle surface, such as steam washing, and reduce environmental pollution through minimization of water usage. Problems such as location restrictions can be solved through minimization of installation area and space.

1 shows a first 2D lidar and a second 2D lidar constituting a vehicle shape data obtaining apparatus used in a method for acquiring shape data of a car according to a first embodiment of the present invention, and a sensor for measuring a vehicle width of an automatic car washing device. This is an image of the installed state.
FIG. 2 shows the result of generating the entire vehicle data by mirroring the point cloud data of the first 2D lidar using the first 2D lidar installed in FIG. 1 and the vehicle width information obtained through the vehicle width measuring sensor.
Figure 3 shows errors in the shape of data caused by water droplets adhering to or scattering from a vehicle.
FIG. 4 shows the result of generating point cloud data acquired through the first 2D lidar and the second 2D lidar installed in FIG. 1 and the entire vehicle data by fusing them.
5 schematically shows a scanning state of laser light when a 1-channel lidar is used as the first 2D lidar.
6 is a data acquisition device according to a second embodiment of the present invention, schematically showing a scan state of laser light using a 2-channel lidar as a first 2D lidar.
7 shows a 3D shape image of a car obtained by using a 2-channel lidar as a first 2D lidar in the data acquisition apparatus according to the second embodiment of the present invention.

Hereinafter, the configuration and operation of embodiments of the present invention will be described with reference to the accompanying drawings.

In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

[Example 1]

1 shows a first 2D lidar and a second 2D lidar constituting a vehicle shape data obtaining apparatus used in a method for acquiring shape data of a car according to a first embodiment of the present invention, and a sensor for measuring a vehicle width of an automatic car washing device. This is an image of the installed state.

As shown in FIG. 1, when a car enters the automatic car wash device, a first 2D lidar (circled on the left side of FIG. marked) is attached on a bracket that protrudes downward from the upper frame on the inlet side of the automatic car wash device.

In addition, a second 2D lidar (circled on the right side of FIG. 1) is attached to the side frame of the entrance side of the automatic car wash device so that shape data can be obtained by scanning the side surface (including some upper surfaces) of the car. Attached by brackets.

In addition, vehicle width measurement sensors for accurately measuring the vehicle width by measuring the distance from the vehicle tire are installed on both sides of the car wash.

In addition, although not shown, a processor (calculator) for receiving information obtained from the first 2D lidar and the second 2D lidar wired or wirelessly and finally performing image fusion processing is the automatic car wash device. It is provided inside (or outside) of.

The 2D LIDAR (Light Detection And Ranging) emits pulsed laser light in the form of scanning at a predetermined angle toward a target (a car entering an automatic car wash in the embodiment of the present invention), and then reflects the laser light back to the target. By capturing the incoming light energy using a photo detector and converting it into an electrical signal, the distance to the target or the moving speed of the target is calculated, and the 3D shape is obtained through the point cloud data for the distance to the target. It is a device capable of calculating data for information (2D, but a 3D image obtained by relative movement with the car).

In addition, in the first embodiment of the present invention, the first 2D lidar is asymmetrically arranged so as to be biased to one side from the center line when drawing a virtual center line based on the longitudinal direction of the vehicle. As shown in FIG. 1, the first 2D lidar is disposed in the upper left corner.

In addition, in the first embodiment of the present invention, the second 2D lidar is disposed at a position capable of scanning the side of the vehicle. The position of the second 2D lidar is most preferably placed within the door area of the car when viewed from the side of the car, but if there is no problem in scanning the side of the car, it may be placed higher than the height of the car. In particular, since the height of cars varies greatly depending on the type of car, such as a sedan or SUV, it is preferable to scan the side of the car regardless of the height of various cars. For example, the height of the second 2D lidar may be adjusted according to the type of vehicle. In this case, it is possible to more accurately obtain shape information of the side of the vehicle.

In addition, in the first embodiment of the present invention, a 1D lidar sensor or a beam sensor is used as the vehicle width measuring sensor. In the case of 1D lidar sensor, it does not provide image information because it does not have a scan function, and it is a lidar that can accurately measure the distance to the target simply, and is significantly cheaper than 2D lidar. The 1D lidar sensor can accurately derive information about vehicle width, for example, by accurately measuring the distance to the wheel of an approaching vehicle.

In addition, although not shown in FIG. 1, the first 2D lidar and the second 2D lidar are installed around the bracket to which the first 2D lidar and the second 2D lidar are attached when the car washing device operates. An air blower may be installed to supply strong air toward the inside of the car wash device so that water droplets scattered toward the vehicle do not come into contact with each other.

A method for obtaining vehicle shape data for an automatic car wash using the first 2D lidar, the vehicle width measurement sensor, the second 2D lidar, and a computer as described above may be implemented in the following three ways.

<In case of using only the first 2D lidar and vehicle width measuring sensor>

First, when a car enters the automatic car wash device of FIG. 1, the first 2D lidar scans the upper surface and one side of the car to obtain point cloud data for distance, thereby acquiring 3D shape information. (see Figure 2).

At this time, the scan of the first 2D lidar is performed in the form of reciprocating from one end to the other end of the upper surface of the car, and at this time, since the car enters the car wash device, the scan is performed in the longitudinal direction of the car. Accordingly, a scan is performed in a zigzag form between one end and the other end of the upper surface of the vehicle.

Further, the vehicle width measurement sensors mounted on both sides of the automatic car wash device are arranged to obtain vehicle width and alignment angle data of the vehicle wash, and measure the vehicle width data based on, for example, the tires of the vehicle entering the car wash.

The computer obtains the shape data of the entire vehicle by correcting information on the width of the 3D shape information obtained from the first 2D lidar based on the obtained accurate vehicle width data and mirroring the center line of the vehicle width as a standard. (See Fig. 2).

According to this method, as confirmed in FIG. 2 , it is possible to obtain precise information about most of the car shapes except for the lower part of the side of the car body. In general, since car body washing does not require precision down to the lower part of the car in most cases, even if the car body shape data obtained by this method is used, not only the efficiency of automatic car washing can be greatly increased, but also the automation of steam car washing can be improved. can make it possible

Meanwhile, the point cloud data shown in FIG. 2 may include a lot of noise. For example, when it is necessary to acquire shape information in a state where there are water droplets scattered in the car wash device, as shown in FIG. 3, there is a possibility that an error in shape information may occur due to refraction, scattering, or reflection of laser light emitted from lidar. there is In this case, data errors can be reduced by using a method of filtering and removing light having a certain intensity or less among the reflected laser light.

<When using the first 2D lidar and the second 2D lidar>

When a car enters the automatic car wash apparatus of FIG. 1, the first 2D lidar and the second 2D lidar scan the upper surface (including some side surfaces) and the side surface (including some upper surfaces) of the car, respectively. Point cloud data about the distance is obtained, and through this, 3D shape information is obtained. At the same time, the scan of the second 2D lidar is performed in the form of reciprocating from the top to the bottom on the side of the car, and like the first 2D lidar, since the car enters the car wash device, scans are performed simultaneously. Accordingly, a scan is performed in a zigzag form at the lower end and the upper end along the longitudinal direction of the vehicle.

FIG. 4 shows shape information obtained through point cloud data obtained through scans of the first 2D lidar and the second 2D lidar arranged as shown in FIG. 1 and shape information derived by fusing them.

The upper left shape of FIG. 4 represents the shape information of the car obtained from the first 2D lidar, and the upper right shape of FIG. 4 represents the shape information of the car obtained from the second 2D lidar.

The shape shown below in FIG. 4 reflects the fact that the shape of the car is left-right symmetrical, extracts precise areas from the shape information obtained from the first 2D lidar and the second 2D lidar, and then fuses them to create the overall car It derives the shape. Through this process, it is possible to relatively accurately obtain vehicle shape information required for automatic car washing using only two lidars.

<In the case of using the first 2D lidar, the second 2D lidar and the vehicle width measuring sensor>

Precise vehicle shape information can be obtained through the fusion of the first 2D lidar and the second 2D lidar, but there is a possibility that an error may occur in the accuracy of the vehicle width. In this case, if vehicle width information obtained from the vehicle width measurement sensor is used to correct the vehicle width and then fuse, it is possible to obtain vehicle shape information with improved vehicle width accuracy.

[Example 2]

5 schematically shows an example of using a 1-channel lidar as a first 2D lidar. As shown in FIG. 5, when emitting a laser by placing a 1-channel lidar on top of a car, due to the angle at which the laser is emitted (in FIG. 5, it is emitted vertically toward the ground), the license plate or , the shape of the rear bumper side is not accurately extracted.

On the other hand, unlike FIG. 5, when the light emission angle of the first 2D lidar of 1 channel is emitted at a predetermined angle along the longitudinal direction of the car rather than perpendicular to the ground, the front license plate portion has precise 3D shape information Extracted but the back side is not precisely extracted, or conversely, the back side is precisely extracted but the back side is not precisely extracted.

Accordingly, in most cases, it is possible to obtain three-dimensional shape information capable of automatic car washing even with the method according to Example 1, but in the case of a car having a shape different from the normal shape of the front or rear part of the car, the front and rear Precise shape information about may be required.

6 schematically shows an example of using a two-channel lidar as a first 2D lidar according to a second embodiment of the present invention. A two-channel lidar is a lidar with two light sources that can scan the laser at different angles.

As shown in FIG. 6, when the angle of the light emitted from the two channels is emitted at a predetermined angle with respect to the longitudinal direction of the car (moving direction of the car or the moving direction of the car wash) (predetermined forward and backward among the two channels) If the laser is emitted obliquely at an angle), precise shape information on license plate and grille shape can be obtained through light emitted from one of the two channels, and light emitted from the other channel can provide information on the rear of the car. Precise shape information can be obtained.

As shown in FIG. 7 , according to the second embodiment of the present invention, it is possible to obtain precise shape information about the shape of not only the front part of the vehicle but also the rear part.

Claims (11)

By using a first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body in the lateral direction, a position including at least the center of the upper surface of the car body and obtaining shape data of the vehicle body by scanning between the sides of the vehicle body;
measuring a width of the vehicle body using a distance sensor disposed at a predetermined height from the ground and separated from one side of the vehicle body by a predetermined distance;
and obtaining overall shape data of the car body by mirroring data of the first 2D lidar using an intermediate distance of the measured car body width. According to claim 1,
The distance sensor is a beam sensor or a 1D lidine, and a vehicle shape data acquisition method for an automatic car wash device. delete delete delete According to claim 1,
The first 2D lidar consists of two channels having two light emitting sources, and the two light emitting sources are spread at a predetermined angle along the length direction of the vehicle body to emit light toward the front and rear, respectively. How to acquire shape data. According to claim 1,
The method of obtaining vehicle shape data for an automatic car wash device, wherein light having a predetermined intensity or less among the light reflected from and received by the first 2D lidar is removed through a filter. A first 2D lidar disposed at a predetermined distance from the upper surface of the car body and a predetermined distance from the center line along the longitudinal direction of the car body;
A distance sensor disposed at a predetermined height from the ground at a predetermined distance from one side of the vehicle body to measure the width of the vehicle body;
Processing data generated by the first 2D lidar and the distance sensor to process data generated by the first 2D lidar and the distance sensor, and mirroring the data of the first 2D lidar using the intermediate distance of the measured width of the car body, thereby obtaining data on the shape of the entire vehicle body A vehicle shape data acquisition device for an automatic car wash device comprising a data processing device that performs a delete delete According to claim 8,
The first 2D lidar includes 2 channels having 2 light emitting sources, and an apparatus for obtaining vehicle shape data for an automatic car wash.

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