KR20230145283A - Apparatus for acquiring an image under a vehicle equipped with an illuminance sensor - Google Patents

Abstract

The present invention is equipped with an illuminance sensor that guides the vehicle's lower area to be fully photographed even if the overall length of the vehicle is long or short, and guides the vehicle entering the vehicle to obtain a clear image of the vehicle's lower body by controlling the stopping and movement. It relates to an image acquisition device for the underside of a vehicle, which induces the slow movement of a vehicle moving on a vehicle access road, and includes a vehicle bump 100 in which a body receiving area 111 is formed to accommodate the body through the central portion of the upper side of the bump body 110. )class; A straight body 200, the lower part of which is seated through the tube receiving area 111 of the bump body 110, and receiving areas 210 formed at predetermined intervals on the upper surface; A load cell 300 installed on the upper side of the bump body 110 to detect when a vehicle steps on the vehicle bump 100 and generate a vehicle detection signal; It is installed on one side of the vehicle access road, parallel to the straight body 200, and is installed at predetermined intervals on the side of the detection body 410 where a vehicle enters. It is installed in each area only when a vehicle is detected. A vehicle overall length confirmation body 400 including a plurality of vehicle detection sensors 420 that generate vehicle detection signals; A camera 230 for securing images of a designated area is installed in each storage area 210 of the straight body 200 and captures a designated area under the vehicle to generate still image information of the designated area. ; When a vehicle detection signal is generated from the load cell 300, the plurality of vehicle detection sensors 420 provided in the vehicle overall length confirmation body 400 are driven and controlled, and the vehicle detection signal for each area is generated by the drive control. The overall length of the vehicle is determined with reference to It includes an operating terminal 500 having a control unit 520 that connects still image information of a designated area under the vehicle generated by drive control to obtain full area underbody still image information representing the entire underbody of the vehicle, It is installed at the rear of the vehicle bump 100, and divides vehicles into large and small depending on the overall length of the vehicle. When the vehicle is classified as large, a one-way direction sign 710 guides the vehicle in one direction and the vehicle It further includes a vehicle length guide unit 700 consisting of a guide sign 720 for the other direction that guides the vehicle in the other direction when classified as small, and the control unit 520 is configured to determine the vehicle size by referring to the vehicle detection signal. Based on the overall length, the operation is controlled by selecting the one-way direction sign 710 and the other side direction sign 720 that form the vehicle length information section 700 according to the large or small size of the vehicle, and the one-side load cell 310 ) and the other side load cell 320 generates a load cell identifier for each installation area that identifies the corresponding load cell in which the vehicle detection signal was generated by collecting the vehicle detection signal, and the control unit 520 generates the one side load cell ( 310) and the other side load cell 320, the overall width length of the vehicle is determined based on the vehicle detection signal generated respectively, and the determined overall width length and overall length of the vehicle are matched with the information storage unit 510 to determine the vehicle's By predicting the type, the lower height (LH1, LH2, LH3) belonging to the predicted vehicle type is recognized, and the overlapping length of the video shooting area for each lower height according to the predicted vehicle lower height (LH1, LH2, LH3) Referring to the information, a designated area generated by drive control, a continuous designated area forming still image information under the vehicle, a designated area on one side of the overlapping still image screens under the vehicle, connected with the overlapped area of the still image screens under the vehicle removed. This performs the function of acquiring still image information of the entire area under the vehicle.

Description

Image acquisition device under a vehicle equipped with an illuminance sensor {Apparatus for acquiring an image under a vehicle equipped with an illuminance sensor}

The present invention is equipped with an illuminance sensor that guides the vehicle's lower area to be fully photographed even if the overall length of the vehicle is long or short, and guides the vehicle entering the vehicle to obtain a clear image of the vehicle's lower body by controlling the stopping and movement. This relates to an image acquisition device under a vehicle.

Recently, due to the instability of the international situation, car bombings against major buildings and people have occurred frequently, and rapidly developing technologies and equipment have been leaked.

Accordingly, vehicle underbody inspection devices, which are devices that search the underside of a vehicle when entering or exiting public parking facilities provided at major institutions, large shopping malls, event halls, and sports facilities, are being proposed.

Searching through an under-vehicle search scope, which is one of these under-vehicle inspection devices, cannot provide an accurate search due to blind spots, and the management personnel must carry the vehicle in person to stop the entering vehicle and then conduct a search one by one. In large facilities with a large influx of people, it takes a lot of time to search under the vehicle, causing inconvenience to users.

To solve this problem, a vehicle underbody inspection device captures image information by filming the underside of the vehicle through a camera, then reads the acquired undervehicle image information to detect bombs, drugs, contraband, etc. attached to the underside of the vehicle (patent document) 1) was proposed.

However, in the conventional vehicle underbody inspection device, a camera that takes pictures of the underside of the vehicle is fixedly installed to take pictures of the underside of the vehicle. Therefore, if the overall length of the vehicle is a short vehicle such as a passenger car, the entire underbody area of the vehicle can be photographed. In the case of long vehicles such as , there is a problem in that the entire lower area of the vehicle cannot be photographed.

KR 10-1773802 B1

The present invention is intended to solve the problems of the prior art, and the purpose of the present invention is to guide the vehicle so that the lower area of the vehicle can be fully photographed even if the overall length of the vehicle is long or short, and to control the stopping and movement of vehicles entering the vehicle. The aim is to provide a vehicle underbody image acquisition device equipped with an illumination sensor that guides the acquisition of clear vehicle underbody images and a vehicle underbody image acquisition method using the same.

As a technical idea for achieving the present invention, the image acquisition device under the vehicle equipped with the illuminance sensor of the present invention is to induce the slow movement of the vehicle moving on the vehicle entrance road, so that the pipe body is penetrated and accommodated along the central portion of the upper side of the bump body. A vehicle bump formed with a body receiving area; A straight body, the lower part of which is seated through the tube receiving area of the bump body, and receiving areas formed at predetermined intervals on the upper surface; A load cell installed on the upper side of the bump body to detect when a vehicle steps on the bump and generate a vehicle detection signal; It is installed on one side of the vehicle access road, parallel to the straight body, and is installed at predetermined intervals on the side of the detection body where a vehicle enters. The beams are connected only when a vehicle is detected, and the entire vehicle is detected. A vehicle overall length confirmation body including a plurality of vehicle detection sensors that generate vehicle detection signals for each overall area representing the lower area; a plurality of cameras for securing images of a designated area, which are mounted and installed in each storage area of the straight body, and capture images of a designated area under the vehicle to generate still image information of the designated area under the vehicle; When a vehicle detection signal is generated from the load cell, a plurality of vehicle detection sensors provided in the vehicle overall length confirmation body are driven and controlled, and the overall length of the vehicle is determined by referring to the vehicle detection signal for each area generated by the drive control. And, among the plurality of cameras for securing images of the designated area, only the cameras for securing images of the designated area that capture images of the area of the determined overall length are driven and controlled, and the still image information of the underside of the vehicle in the designated area generated by the driving control is connected. It includes an operating terminal having a control unit that acquires still image information of the entire area under the vehicle, which represents the entire lower area of the vehicle, and is installed at the rear of the vehicle bump, and can be divided into large and small vehicles according to the overall length of the vehicle. It further includes a vehicle length-specific guidance section consisting of a one-way direction sign that guides in one direction when the vehicle is classified as a large vehicle and a guide sign in the other direction that guides the vehicle in the other direction when the vehicle is classified as a small vehicle; The control unit selects and controls the operation of the one-way guide sign and the other-way guide sign forming the guide section for each vehicle length according to the large or small size of the vehicle based on the overall length of the vehicle determined with reference to the vehicle detection signal, and the straight body It is installed in each storage area of, and further includes a light emitting unit that illuminates the lower part of the vehicle, and further includes an illuminance sensor that detects the ambient illuminance of the vehicle entrance and generates an illuminance detection signal, and the control unit detects the generated illuminance. If the illuminance intensity of the detection signal is lower than the illuminance intensity value of the lighting driving reference information requesting the lighting operation, a function is performed to control the light emitting unit to turn on.

The present invention has the effect of guiding the vehicle's lower area to be fully photographed even if the overall length of the vehicle is long or short, and guiding vehicles entering the vehicle to obtain a clear image of the vehicle's lower body by controlling the stopping and movement.

In addition, in the present invention, each camera is installed on the road floor at regular intervals, so that when photographing the lower part of the vehicle in each designated area, even if an overlapping area occurs between captured images at different lower heights depending on the overall width and overall length of the vehicle, the camera remains intact. It also has the effect of providing guidance to obtain images of the underside of the vehicle.

In addition, the present invention has the effect of allowing the underside of the vehicle to be recognizable even if the surrounding brightness becomes dark due to weather factors.

In addition, the present invention has the effect of guiding the vehicle into a parking space of the corresponding size according to the size or size of the vehicle to be parked after obtaining an image of the underside of the vehicle.

1 is an overall configuration diagram showing an image acquisition device under a vehicle equipped with an illumination sensor of the present invention.
Figure 2 is a perspective view showing a vehicle bump and a straight body part among the components of the image acquisition device under the vehicle equipped with the illuminance sensor of the present invention.
Figure 3 is a block diagram showing each component that is controlled through an operation terminal among the components that make up the image acquisition device under the vehicle equipped with the illuminance sensor of the present invention.
Figure 4 is a diagram expressing different lower heights depending on the overall width and length of the vehicle.
Figure 5 is a diagram expressing the degree of overlap when photographing the lower part of a vehicle in each designated area at different lower lower heights depending on the overall width and overall length of the vehicle.
Figure 6 is a diagram showing how to obtain a complete image of the underside of a vehicle by removing overlapping parts and connecting them when photographing the underside of a vehicle in each designated area at different underside heights depending on the overall width and overall length of the vehicle.
7 and 8 are flowcharts showing a method of acquiring an image of the underside of a vehicle using an under-vehicle image acquisition device equipped with an illumination sensor of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. The present embodiments only serve to ensure that the disclosure of the present invention is complete and that common knowledge in the technical field to which the present invention pertains is not limited. It is provided to fully inform those who have the scope of the invention, and the invention is defined by the claims.

Meanwhile, the terms used in this specification are for describing embodiments and are not intended to limit the present invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, “comprises” and/or “comprising” refers to the presence of one or more other elements, steps, operations and/or elements in the mentioned elements, steps, operations and/or elements. or addition is not excluded. Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

As shown in Figures 1 to 6, the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention largely includes a vehicle bump 100, a straight body 200, a load cell 300, and a vehicle overall length confirmation body 400. ), a camera 230 for securing images of a designated area, and an operation terminal 500.

First, the vehicle bump 100 is fixedly installed on the road floor to induce slow movement of vehicles moving on the vehicle entrance road, and a pipe receiving area 111 is formed along the central portion of the upper side of the bump body 110 to accommodate the pipe body through it. It is a formed member.

In particular, load cells 300 to be described later for detecting the weight of an entering vehicle are installed on the left and right sides of the bump body 110 centered on the tube receiving area 111 of the bump body 110. At this time, the load cell 300 ) A joint 112 is formed so that the left and right sides of the bump main body 110 communicate for operation control and power supply.

The straight body 200 has a seating groove 220 on the lower surface that spans the joint 112 of the bump body 110 so that the lower part is seated through the tube receiving area 111 of the bump main body 110. It is a member that is recessed and has storage areas 210 formed at predetermined intervals on the upper surface.

*Meanwhile, each storage area 210 is provided with a camera 230 and a light emitting unit 240 for securing images of a designated area, which will be described later.

The load cell 300 is a member that is installed on the upper side of the bump body 110 and detects when a vehicle steps on the vehicle bump 100 and generates a vehicle detection signal.

The vehicle overall length confirmation body 400 is installed on one side of the vehicle access road, parallel to the straight body 200, and is installed at predetermined intervals on the side of the detection body 410 into which the vehicle enters. , It is a member that includes a plurality of vehicle detection sensors 420 that generate a vehicle detection signal for each area only when a vehicle is detected.

Here, the vehicle detection sensor 420 may use an optical sensor.

Meanwhile, since the vehicle overall length confirmation body 400 is a member that performs the function of detecting the side of the vehicle, it must be located higher than the wheels of the vehicle. Therefore, rod-shaped supports are provided at regular intervals in the lower part of the sensing body 410. (430) can be provided for installation.

The camera 230 for securing images of the designated area is installed in each storage area 210 of the straight body 200, and is a plurality of cameras that capture the designated area under the vehicle and generate still image information of the designated area under the vehicle. There is a lack of video filming.

Here, the still image information of the underside of the vehicle in the designated area being captured is a still image.

When a vehicle detection signal is generated from the load cell 300, the operation terminal 500 drives and controls a plurality of vehicle detection sensors 420 provided in the vehicle overall length confirmation body 400, and through the drive control. A camera 230 for securing a designated area image determines the overall length of the vehicle by referring to the vehicle detection signal for each area generated, and photographs a portion of the area with the determined overall length among the plurality of cameras 230 for securing an image for the designated area. ), and is a terminal member having a control unit 520 that connects the still image information of the designated area under the vehicle generated by the drive control to obtain the still image information of the entire area of the vehicle under the vehicle representing the entire underbody of the vehicle. .

The operation terminal 500 that performs this function includes a vehicle detection signal generated by the load cell 300, a vehicle detection signal for each area generated by the vehicle detection sensor 420, and a camera 230 for securing images of a designated area. An information and communication unit 530, which is an interfacing member for transmitting and receiving still image information of the underside of a vehicle in a designated area, is provided.

The information and communication unit 530, which performs these functions, uses wired communication including Ethernet, wireless LAN (WLAN), Bluetooth, Wi-Fi, wireless broadband, Wibro, and WiMAX. It can be used selectively among wired and wireless communication methods such as wireless communication including Interoperability for Microwave Access (Wimax) and HSDPA (High Speed Downlink Packet Access).

Meanwhile, the operation terminal 500 is installed and provided in a place operated by public parking facilities provided at major institutions, large shopping malls, event halls, and sports facilities, and detects dangerous substances such as bombs by reading the acquired still image information of the entire area under the vehicle. It can also perform a detection function.

Meanwhile, in the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention, each camera is installed on the road floor at regular intervals, and when photographing the underside of the vehicle in each designated area, the underbody height varies depending on the overall width and overall length of the vehicle. It provides the advantage of providing guidance so that a complete image of the underside of the vehicle can be obtained even if there are overlapping areas between individually captured images.

For this purpose, the load cell 300 in the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention includes a first load cell 311 on one side installed at a predetermined interval on one upper side of the bump body 110, One side load cell 310 consisting of a second load cell 313 on one side and a third load cell 315 on one side, and a first load cell 321 on the other side installed at a predetermined interval on the other upper side of the bump body 110. , It consists of a second load cell 323 on the other side and a third load cell 325 on the other side.

And the operation terminal 500 includes an information storage unit 510, and the information storage unit 510 classifies the type of vehicle by the overall length and width of the vehicle, and the overall length and width of the vehicle. Bottom height information representing the bottom height (LH1, LH2, LH3) for each type of vehicle divided by the overall width and length of the vehicle is stored and managed separately for each type of vehicle, and the bottom height (LH1, LH3) for each type of vehicle is stored. The overlapping length information of the video shooting area by lower height, which displays the overlapping length of the still image information of the underside of the vehicle in the designated area captured through the camera 230 for securing images of the designated area spaced at predetermined intervals according to LH2, LH3), is stored and managed. It is done. The information storage unit 510 that performs this function includes flash memory type, hard disk type, multimedia card micro type, and card type memory (e.g. For example, SD or Read-Only Memory), magnetic memory, magnetic disk, optical disk, or a combination thereof.

Through this, the one side load cell 310 and the other side load cell 320 generate a load cell identifier for each installation area that identifies the corresponding load cell in which the vehicle detection signal was generated by collecting it with the vehicle detection signal, and generate this through the operation terminal ( 500).

The control unit 520 of the operation terminal 500 determines the overall width length of the vehicle based on the vehicle detection signal generated from the one side load cell 310 and the other side load cell 320, and the determined overall width length of the vehicle. And predict the type of vehicle by matching the overall length with the information storage unit 510, recognize the lower height (LH1, LH2, LH3) belonging to the predicted type of vehicle, and the lower height of the predicted vehicle ( Referring to the video shooting area overlap length information for each lower height according to LH1, LH2, LH3), one overlapped side of the consecutive designated area vehicle lower still image screens that constitute the designated area vehicle lower still image information generated by drive control Obtain still image information of the entire area of the vehicle underbody by connecting them with the overlapping areas of the still image screens under the vehicle in the designated area removed.

This is explained in detail using drawings as follows.

Figure 4 is a diagram showing different lower heights depending on the overall width and overall length of the vehicle. Typically, vehicles are passenger cars (C1) with a short overall length or overall width, and SUVs with overall length or overall width generally longer than passenger cars (C1). (C2) and overall length and width are generally longer than passenger cars (C1) or SUVs (C2), so they can be classified as large vehicles (C3), including buses and specially equipped vehicles.

The bottom height according to the overall length and width of the vehicle is generally lower than that of a passenger car (C1) (LH1), and that of a large vehicle (C3) is lower than that of a passenger car (C2). It is higher than the lower height (LH1) of (C1) and the lower height (LH2) of SUV (C2).

Such differences are subdivided by model of each vehicle and stored and managed in the information storage unit 510.

And with reference to FIG. 5, overlap occurs when filming the lower part of the vehicle through the camera 230 for securing images of a designated area spaced at a predetermined interval according to the lower height (LH1, LH2, LH3) for each type of vehicle. do.

For this reason, with the cameras 230 for securing images of each designated area placed at intervals that do not cause overlap when shooting, based on the model with the lowest lower height (LH1) among the passenger cars (C1), ) It can be seen that the overlapping area becomes longer for SUVs (C2) and large vehicles (C3) with lower lower heights.

Accordingly, referring to FIG. 6, when photographing the underside of the vehicle in each designated area for different lower part heights (LH1, LH2, LH3) depending on the overall width and length of the vehicle, the length of the overlapping part is predicted, and the underside of the vehicle in successive designated areas is predicted. Remove the overlapping area of the still image screens of the underbody of the vehicle in the designated area of one of the overlapping still image screens (in this embodiment, the designated area located on the left among the still image screens of the underbody of the two shared overlapping designated areas under the vehicle) It guides you to obtain still image information of the entire area under the vehicle by connecting while the video screen is on.

In addition, the under-vehicle image acquisition device equipped with the illuminance sensor of the present invention provides the advantage of perceptibly capturing images of the underside of the vehicle even if the surrounding brightness becomes dark due to weather factors.

For this purpose, the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention is installed in each storage area 210 of the straight body 200 and further includes a light emitting unit 240 that illuminates the lower part of the vehicle. That is, the camera 230 for securing images of a designated area and the light emitting unit 240 are provided as a set.

In addition, it further includes an illuminance sensor 120 that detects the ambient illuminance of the vehicle access road and generates an illuminance detection signal.

Through this, the control unit 520 of the operation terminal 500 turns on the light emitting unit 240 when the illuminance intensity of the generated illuminance detection signal is lower than the illuminance intensity value of the reference information for lighting driving that requests driving of the lighting. The control function is performed as much as possible, but if the illuminance intensity of the illuminance detection signal transmitted from the illuminance sensor 120 at a predetermined period is lower than the illuminance intensity value of the reference information for lighting operation requesting lighting operation, the designated camera operation control is performed. By means of a signal, a designated light emitting unit lighting control signal is generated to control the lighting of each light emitting unit 240 composed of a camera 230 for securing an image of each designated area for photographing the lower part of the vehicle, and this is sent to the information and communication unit 530. By transmitting to a plurality of light emitting units 240 mounted and installed in each storage area 210 of the straight body 200, a plurality of light emitting units ( 240), a function is performed to control lighting of only the corresponding light emitting units 240 according to the lighting control signal of the designated light emitting unit.

In addition, the under-vehicle image acquisition device equipped with the illuminance sensor of the present invention provides the advantage of controlling the stopping and movement of vehicles entering the vehicle so that a clear under-vehicle image can be obtained.

For this purpose, the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention is installed at the rear of the vehicle bump 100 and further includes a parking block 600 equipped with a blocking bar 610 to block the vehicle from moving. do.

Through this, the control unit 520 of the operation terminal 500 performs a function of controlling the blocking rod 610 of the parking barrier 600 to rotate and open after acquiring still image information of the entire area of the vehicle underside.

The under-vehicle image acquisition device equipped with the illuminance sensor of the present invention provides the advantage of obtaining an image under the vehicle and guiding the vehicle into a parking space of the corresponding size according to the size of the vehicle to be parked.

For this purpose, the vehicle underbody image acquisition device equipped with the illuminance sensor of the present invention is installed at the rear of the vehicle bump 100, and the vehicle is divided into large and small according to the overall length of the vehicle, and the vehicle is divided into large. In this case, it further includes a guidance unit 700 for each vehicle length, which consists of a one-way direction sign 710 that guides in one direction and a other direction sign 720 that guides in the other direction if the vehicle is classified as small.

Through this, the control unit 520 of the operation terminal 500 displays a one-way guide sign forming the guide unit 700 for each vehicle length according to the large or small size of the vehicle based on the overall length of the vehicle determined with reference to the vehicle detection signal. It performs the function of controlling the operation by selecting (710) and the other direction sign (720).

The method of acquiring an image of the underside of a vehicle using the under-vehicle image acquisition device equipped with the illuminance sensor of the present invention configured as described above will be described using FIGS. 7 and 8 as follows.

First, a vehicle moving into a vehicle access road where a vehicle underbody image acquisition device equipped with an illumination sensor of the present invention is installed enters the vehicle bump 100, and the load cell 300 protruding from the vehicle bump 100 is pressed and contacted (S100). ), the load cell 300 generates a vehicle detection signal by pressurizing contact with the vehicle and transmits it to the operation terminal 500 (S110).

When the vehicle detection signal transmitted from the load cell 300 is input through the information and communication unit 530, the control unit 520 of the operation terminal 500 recognizes this and detects a plurality of vehicles provided in the vehicle overall length confirmation body 400. A drive control signal for checking the overall length that drives the detection sensor 420 is generated, and this is sent to a plurality of vehicle detection sensors 420 installed at regular intervals on the vehicle overall length confirmation body 400 through the information and communication unit 530. Transmit (S120).

A plurality of vehicle detection sensors 420 installed at regular intervals on the vehicle overall length confirmation body 400 sense by the drive control signal for confirmation of overall length transmitted from the control unit 520, and detect only when a vehicle is detected in front. Generating a vehicle detection signal for each area and transmitting it to the operation terminal 500 (S130);

The control unit 520 of the operation terminal 500 determines the overall length of the vehicle by referring to the vehicle detection signals for each area transmitted from the plurality of vehicle detection sensors 420 installed at regular intervals on the vehicle overall length confirmation body 400. And, among the plurality of cameras 230 for securing images of a designated area installed in each storage area 210 of the straight body 200, only the camera 230 for securing images of a designated area located in the area of the determined overall length is used. A designated camera drive control signal is generated to control the drive to perform filming, and a plurality of cameras 230 for securing images of a designated area are installed in each storage area 210 of the straight body 200 through the information and communication unit 530. ) and transmit (S140).

Meanwhile, the illuminance sensor 120 detects the ambient illuminance of the vehicle access road at predetermined intervals, generates an illuminance detection signal, and transmits it to the operation terminal 500 (S141).

And the control unit 520 of the operation terminal 500 sends an illuminance detection signal transmitted at predetermined intervals from the illuminance sensor 120, if the illuminance intensity is less than the illuminance intensity value of the reference information for lighting operation requesting driving of lighting, The designated camera driving control signal generates a designated light emitting unit lighting control signal that controls the lighting of each designated area image securing camera 230 for photographing the underside of the vehicle and each light emitting unit 240 in a group, and generates a designated light emitting unit lighting control signal. It is transmitted to a plurality of light emitting units 240 installed in each storage area 210 of the straight body 200 through the information and communication unit 530 (S142).

Through this, in the plurality of cameras 230 for securing images of a designated area installed in each storage area 210 of the straight body 200, the corresponding camera is activated by a designated camera drive control signal transmitted from the control unit 520. Only the cameras 230 for securing images in the designated area capture the underside of the vehicle to generate still image information of the underside of the vehicle in the designated area, and in the process of transmitting this (S150), they are seated in each storage area 210 of the straight body 200. Even in the plurality of light emitting units 240 installed, only the corresponding light emitting units 240 are turned on (S143) by the designated light emitting unit lighting control signal transmitted from the control unit 520, thereby providing clearer still image information of the underside of the vehicle in the designated area. Guides you to create a .

Thereafter, the control unit 520 of the operation terminal 500 selects a designated camera drive control signal among a plurality of cameras 230 for securing images of a designated area installed in each storage area 210 of the straight body 200. By connecting the still image information of the designated area under the vehicle transmitted from the cameras 230 for securing area images, still image information of the entire area under the vehicle representing the entire underbody of the vehicle is obtained (S160). The detailed process is as follows. .

The control unit 520 of the operation terminal 500 determines the overall width length of the vehicle based on the vehicle detection signal generated from the one side load cell 310 and the other side load cell 320, and the determined overall width length of the vehicle. And predict the type of vehicle by matching the overall length with the information storage unit 510, recognize the lower height (LH1, LH2, LH3) belonging to the predicted type of vehicle, and the lower height of the predicted vehicle ( Referring to the video shooting area overlap length information for each lower height according to LH1, LH2, LH3), one overlapped side of the consecutive designated area vehicle lower still image screens that constitute the designated area vehicle lower still image information generated by drive control Obtain still image information of the entire area of the vehicle underbody by connecting them with the overlapping areas of the still image screens under the vehicle in the designated area removed.

Thereafter, the control unit 520 of the operation terminal 500 acquires still image information of the entire area of the vehicle underside and then controls the blocking rod 610 of the blocked parking breaker 600 to be opened by rotating (S170).

Thereafter, the control unit 520 of the operation terminal 500 displays a one-way guide sign ( 710) and the other direction guide sign 720 are selected to perform operation control (S180).

In the above description, the present invention has been shown and described in relation to specific embodiments, but it is known to those skilled in the art that various modifications and changes are possible without departing from the spirit and scope of the invention as indicated by the claims. Anyone who has it will be able to easily understand it.

100: vehicle bump 110: bump body
111: tubular receiving area 112: joint jaw
120: Illuminance sensor 200: Straight body
210: Storage area 220: Placement home
230: Camera for securing images of designated area
240: light emitting unit 300: load cell
310: One-side load cell 311: One-side first load cell
313: second load cell on one side 315: third load cell on one side
320: Other side load cell 321: Other side first load cell
323: second load cell on the other side 325: third load cell on the other side
400: Vehicle overall length confirmation body 410: Detection body
420: Vehicle detection sensor 430: Support body
500: Operation terminal 510: Information storage unit
520: Control Department 530: Information and Communication Department
600: parking breaker 610: blocking rod
700: Information section for each vehicle length 710: Direction sign on one side
720: Other direction sign

Claims (2)

A vehicle bump 100, which is used to induce slow movement of vehicles moving on a vehicle access road, is formed with a tube receiving area 111 along the central portion of the upper side of the bump body 110 to accommodate the tube body through;
A straight body 200, the lower part of which is seated through the tube receiving area 111 of the bump body 110, and receiving areas 210 formed at predetermined intervals on the upper surface;
A load cell 300 installed on the upper side of the bump body 110 to detect when a vehicle steps on the vehicle bump 100 and generate a vehicle detection signal;
It is installed on one side of the vehicle access road, parallel to the straight body 200, and is installed at predetermined intervals on the side of the detection body 410 where a vehicle enters. It is installed in each area only when a vehicle is detected. A vehicle overall length confirmation body 400 including a plurality of vehicle detection sensors 420 that generate vehicle detection signals;
A camera 230 for securing images of a designated area is installed in each storage area 210 of the straight body 200 and captures a designated area under the vehicle to generate still image information of the designated area. ;
When a vehicle detection signal is generated from the load cell 300, the plurality of vehicle detection sensors 420 provided in the vehicle overall length confirmation body 400 are driven and controlled, and the vehicle detection signal for each area is generated by the drive control. The overall length of the vehicle is determined with reference to It includes an operating terminal 500 having a control unit 520 that connects still image information of a designated area under the vehicle generated by drive control to obtain full area underbody still image information representing the entire underbody of the vehicle,
It is installed at the rear of the vehicle bump 100, and divides the vehicle into large and small depending on the overall length of the vehicle. When the vehicle is classified as large, a one-way guide sign 710 that guides the vehicle in one direction and the vehicle When classified as small, it further includes a vehicle length-specific guidance unit (700) consisting of a direction sign (720) for guiding the other direction,
The control unit 520 provides one-way guidance sign 710 and other-way guidance forming the guide unit 700 for each vehicle length according to the large or small size of the vehicle based on the overall length of the vehicle determined with reference to the vehicle detection signal. Control the operation by selecting the sign 720,
An image acquisition device under a vehicle equipped with an illumination sensor, further comprising a light emitting unit 240 that is installed in each storage area 210 of the straight body 200 and illuminates the lower part of the vehicle.
According to paragraph 1,
It further includes an illuminance sensor 120 that detects the ambient illuminance of the vehicle access road and generates an illuminance detection signal,
The control unit 520 controls the light emitting unit 240 to turn on when the illuminance intensity of the generated illuminance detection signal is lower than the illuminance intensity value of the reference information for lighting driving that requests driving of the lighting. Vehicle underbody image acquisition device equipped with sensors.