CN112966352A - System and method for rapidly calculating vehicle deformation collision energy in traffic accident - Google Patents

Abstract

The invention belongs to the technical field of traffic accident information, and particularly relates to a system and a method for quickly calculating vehicle deformation collision energy in a traffic accident. The specific technical scheme is as follows: selecting a known accident vehicle, calculating energy lost due to deformation in the collision process according to the vehicle speed before collision and the vehicle speed after collision, dividing the known accident vehicle into a plurality of continuous cell units, measuring the number of the deformed cell units and the corresponding deformation amount, taking the lost energy as a training sample, and calculating the rigidity coefficient of the deformed cell units by using a convolutional neural network algorithm; selecting a plurality of accident vehicles, and training for a plurality of times until the rigidity coefficients of all the cell units are calculated; and when collision actually occurs, calculating the energy loss caused by deformation according to the number of the deformed cell units and the corresponding rigidity coefficients. The method has high calculation precision, does not need a complex modeling process and has quick calculation time; and the calculated energy absorbed by the collision deformation part of the vehicle is closer to the real data.

Description

System and method for rapidly calculating vehicle deformation collision energy in traffic accident

Technical Field

The invention belongs to the technical field of traffic accident information, and particularly relates to a system and a method for quickly calculating vehicle deformation collision energy in a traffic accident.

Background

Most traffic accidents are car collision accidents, and the collision accidents have the following characteristics: the vehicles exchange energy mutually, the collision part is easy to damage (plastic deformation), and the collision vehicles repel each other (elastic deformation), so that the momentum conservation and energy conservation laws are met. For the division of traffic accident responsibility, calculating the vehicle speed before and after the vehicle collision is a very critical factor, and the vehicle speed before the collision can be calculated according to the energy absorbed by the vehicle deformation and the vehicle speed after the collision; the speed of the vehicle after collision can be calculated according to the ground brake marks and the motion track of the vehicle after collision.

At present, two methods for calculating the energy absorbed by deformation during vehicle collision exist.

The method is characterized in that a two-dimensional simplified calculation model is given, the deformation size of a deformation part when a vehicle collides in an accident is measured, and the absorbed energy is calculated according to the deformation size and the fixed rigidity of the vehicle.

The other method is to use PC-CRASH software for simulation, wherein the software models parts of each part of the vehicle and provides each part assembly with an independent rigidity coefficient, and the simulation calculation is carried out according to the multi-rigid-body dynamics mode during collision to obtain the energy absorbed by the collision deformation part of the vehicle.

Disclosure of Invention

The invention aims to provide a system and a method for quickly calculating vehicle deformation collision energy in a traffic accident.

In order to achieve the purpose of the invention, the technical scheme adopted by the invention is as follows: a method for quickly calculating vehicle deformation collision energy in a traffic accident comprises the steps of selecting a known accident vehicle, calculating energy lost due to deformation in a collision process according to the vehicle speed before collision and the vehicle speed after collision, dividing the known accident vehicle into a plurality of continuous cell units, measuring the number of the deformed cell units and the corresponding deformation amount of the deformed cell units, taking the lost energy as a training sample, and calculating the rigidity coefficient of the deformed cell units by utilizing a CNN convolutional neural network algorithm; selecting a plurality of accident vehicles of the same type, and training for a plurality of times until the rigidity coefficients of all the cell units are calculated; and when collision actually occurs, calculating the energy loss caused by deformation according to the number of the deformed cell units and the corresponding rigidity coefficients.

Preferably: comprises the following steps of (a) carrying out,

a1, selecting the known accident vehicle according to the speed v before the accident vehicle collides₁Post-collision velocity v₂Calculating the energy loss E of the deformation occurring during the collision₀；

A2, establishing a three-dimensional model of the accident vehicle, dividing the accident vehicle into n continuous cell units in a three-dimensional space, and recording the rigidity coefficient of each cell unit as C₁、C₂、C₃……C_n-1、C_n；

A3, measuring the number a of deformed cell units in the deformed area of the accident vehicle and the corresponding deformation amount b of each deformed cell unit, and marking the cell units in a three-dimensional model;

a4, loss of energy E₀As a training sample, the stiffness coefficient C is set_nAs an output result, calculating the rigidity coefficient C of each deformed cell unit by using a CNN convolutional neural network algorithm_n；

A5, selecting a plurality of accident vehicles of the same type, repeating the steps A1-A4 for a plurality of times of training, and obtaining the rigidity coefficient C of each cell unit of the accident vehicles_n；

A6, the number a of cells that deform in response to the vehicle in the actual collision, and the corresponding stiffness coefficient C_nCalculating the loss energy E₀。

Preferably: in the step a3, the deformation amount b is a ratio of cell unit deformation, and b ═ V is calculated₀-V)/V₀*100％，V₀Is the volume of the cell unit before deformation, and V is the volume of the cell unit after deformation.

Preferably: in the step a3, the deformation amount b is a ratio of cell unit deformation, and 4 grades are set, which are 25%, 50%, 75%, and 100%, respectively.

Preferably: in the step A1-A6, the cell units are of a regular hexahedron type.

Preferably: in the step a5, the energy loss E caused by the deformation of the same type of vehicle is classified according to the type of vehicle, the actual vehicle weight of the vehicle, the vehicle wheel base, the vehicle driving style and the vehicle power source₀The calculation is performed as a training sample of the same group.

Correspondingly: the system comprises a user side and a database, wherein the user side comprises a photographing module, a three-dimensional modeling module, an image comparison module and an energy loss calculation module, the photographing module is used for photographing an accident vehicle and uploading a picture to the three-dimensional modeling module, the three-dimensional modeling module establishes a vehicle three-dimensional model according to the picture of the vehicle, the image comparison module compares the accident vehicle three-dimensional model with a vehicle three-dimensional model of a vehicle with the model, and determines a region deformed due to collision and a deformation amount of the region, and the energy loss calculation module can calculate energy loss caused by collision deformation according to the region deformed due to collision and the deformation amount of the region, and a rigidity coefficient stored in the database; and data are interacted between the database and the user side.

Preferably: and three-dimensional models of vehicles of different models and the rigidity coefficient of each cell unit are stored in the database.

Preferably: the management end comprises a rigidity coefficient calculation module, a statistical analysis module and a classification query module, wherein the rigidity coefficient calculation module can calculate the rigidity coefficient of the cell unit according to energy loss caused by collision deformation, store the calculated rigidity coefficient into a database according to the type of the vehicle, and continuously update the rigidity coefficient of the vehicle cell unit corresponding to the database; the statistical analysis module can analyze safe driving speeds, vehicle easily-damaged parts, vehicle collision-resistant parts and the like of different vehicles according to user requirements; the classification query module can query the rigidity coefficients of different vehicles and different parts according to the needs of a user; and data is interacted among the management end, the user end and the database.

Compared with the prior art, the invention has the following beneficial effects:

1. the method divides the automobile model into an infinite number of continuous cell units, defines a rigidity coefficient for each cell unit, and calculates the energy absorbed by the collision deformation part of the automobile based on the rigidity coefficient and the deformation of the deformed cell unit.

2. In the invention, a real accident vehicle is adopted as an accident vehicle model in the early period, the number and the deformation amount of the cell units in the deformation area are measured, the rigidity coefficient of the deformed cell units is calculated based on the data, and the certain authenticity of the rigidity coefficient is given to the cell units, so that the calculated energy absorbed by the collision deformation part of the vehicle is closer to the real data.

Drawings

FIG. 1 is a flow chart of a method for rapidly calculating vehicle deformation collision energy in a traffic accident according to the present invention;

FIG. 2 is a block diagram of a system for rapidly calculating vehicle deformation collision energy in a traffic accident according to the present invention;

FIG. 3 is a schematic diagram of cellular element division of a three-dimensional model of an automobile according to the present invention.

The labels in the figure are:

the system comprises a user side 1, a photographing module 11, a three-dimensional modeling module 12, an image comparison module 13 and an energy loss calculation module 14; the system comprises a management end 2, a rigidity coefficient calculation module 21, a statistical analysis module 22 and a classification query module 23; a database 3.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. Unless otherwise specified, the technical means used in the examples are conventional means well known to those skilled in the art.

As shown in fig. 1, the method for rapidly calculating vehicle deformation collision energy in a traffic accident according to the present invention selects a known accident vehicle, calculates energy lost due to vehicle deformation during a collision process according to a vehicle speed before collision and a vehicle speed after collision, divides the accident vehicle into a plurality of continuous cell units, each cell unit corresponds to an independent stiffness coefficient, measures the number of deformed cell units and the corresponding deformation, uses the lost energy as a training sample, uses the stiffness coefficient of the deformed cell units as an output result, and calculates the stiffness coefficient of each deformed cell unit by using a CNN convolutional neural network algorithm; training for multiple times until the rigidity coefficients of all the cell units are calculated; when collision actually occurs, the energy lost due to the deformation is calculated according to the number of the cell units deformed in the collision process and the corresponding rigidity coefficients.

As a specific embodiment of the invention, the method for rapidly calculating the vehicle deformation collision energy in the traffic accident comprises the following steps,

a1, selecting the known accident vehicle according to the speed v before the accident vehicle collides₁Post-collision velocity v₂Calculating the energy loss E of the deformation during the collision₀Loss of energy E₀The calculation formula is E₀＝1/2mv₁ ²-1/2mv₂ ²In order to simplify the calculation, the energy lost by collision deformation only considers the kinetic energy change and does not consider the heat energy generated by collision friction; note that the pre-collision velocity v₁Post-collision velocity v₂Can be based on live videoMonitoring or vehicle crash event recording system (CDR) acquisition;

a2, establishing a three-dimensional model of the accident vehicle, dividing the accident vehicle into n continuous cell units in a three-dimensional space, and recording the rigidity coefficient of each cell unit as C₁、C₂、C₃……C_n-1、C_n(ii) a The vehicle three-dimensional modeling can adopt any one of T-springs software, 3DFZephyr software, Solidworks software and the like, the T-springs software and the 3DFZephyr software are optimized, the 3DF Zephyr software can directly convert a real object picture into a three-dimensional model, a plurality of vehicle appearance pictures with different angles are prepared, and the pictures are taken around the vehicle for one circle at three heights, so that the vehicle high-precision three-dimensional modeling can be carried out;

a3, measuring the deformation area of the accident vehicle on site, measuring the number a of deformed cell units in the deformation area and the corresponding deformation b, and marking in a three-dimensional model; or photographing the collided vehicle by using 3DFZephyr software to establish a three-dimensional model of the collided vehicle, comparing the three-dimensional model of the vehicle before collision, and recording and measuring the number a of deformed cell units in a deformation region and the deformation b of each deformed cell unit;

a4, will lose energy E₀As a training sample, the stiffness coefficient C of the cell unit to be deformed_nAs a result of the output, a rigidity coefficient C of each cell unit that is deformed is calculated_n(ii) a It should be noted that, the stiffness coefficient C of each cell unit is calculated by using the CNN convolutional neural network algorithm_n. The CNN convolutional neural network algorithm uses an algorithm module carried in Python Tensiow software or an existing algorithm module in other software.

A5, selecting a plurality of accident vehicles of the same type and different deformation areas, repeating the steps A1-A4, and obtaining the rigidity coefficient C of each cell unit of the accident vehicle after a plurality of times of training_n；

A6, calculating the loss energy E according to the number a of the cell units deformed by the vehicle and the corresponding rigidity coefficient C when the vehicle actually collides₀。

Further, the stepsIn step a3, the deformation amount b is the rate at which a cell unit is deformed, and b is calculated by the method of (V ═ V)₀-V)/V₀*100％，V₀When the deformation amount of the vehicle collision part is more regular, the three-dimensional model can quickly calculate the cell deformation proportion through comparison, for example, the longitudinal beam of the engine compartment collapses after collision, and the collapse length can accurately reflect through pictures.

Further, in the step a3, the deformation amount b is a ratio of cell deformation, and 4 levels, 25%, 50%, 75% and 100% are provided, and when the deformation of the vehicle collision region is irregular, such as a part of the fender panel is collapsed and twisted after the vehicle is collided with by an oblique collision, the deformation ratio of the cell can be adjusted by manually selecting the deformation ratio.

The two modes can be used respectively or in combination, for example, for a regular part deformed after vehicle collision, the proportion of deformation of the cell units is automatically calculated, and an irregular part deformed at the vehicle collision part is manually set, so that the proportion of deformation of each cell unit can be quickly and accurately set.

Further, in the step a1-a 6, the cell unit may be any one of a cuboid, a cube, a hexahedron and other polyhedrons, preferably a hexahedron, and the cell unit is divided for the three-dimensional model of the vehicle, a mesh division method in finite element software may be adopted, as shown in fig. 3, after the three-dimensional model is built in CATIA or SolidWorks software, the model is directly introduced into ansys or hypermesh software for automatic division, and for a vehicle under the same group of training samples, a plurality of three-dimensional models may be directly simplified into one model.

Further, in order to avoid the lack of training samples, in the step a5, the vehicles are classified according to the type of the vehicle, the actual vehicle weight, the vehicle wheel base, the vehicle driving style and the vehicle power source, and the lost energy E of the same type of vehicle is deformed₀Calculating as training samples of the same group; the vehicle types can be divided into saloon cars, SUVs, MPVs, light trucks and medium trucksDifferent vehicle types are further subdivided through various parameters of the vehicles, such as pure electric vehicles, hybrid vehicles and fuel vehicles, and the fuel vehicles are further divided into front drive, rear drive and four-wheel drive; it should be noted here that, for vehicles of different brands, when each parameter is relatively close, the vehicle can be used as the same training sample group, and a plurality of collision experiments prove that when each parameter of the vehicle is relatively close, the rigidity coefficients of the vehicle body are relatively consistent, so that a large number of training samples can be rapidly accumulated, and the training accuracy is ensured.

As shown in fig. 2, the system for rapidly calculating vehicle deformation collision energy in a traffic accident according to the present invention includes a user end 1 and a database 3, where the user end 1 includes a photographing module 11, a three-dimensional modeling module 12, an image comparison module 13 and an energy loss calculation module 14, the photographing module 11 is electrically or wirelessly connected to the three-dimensional modeling module 12, the three-dimensional modeling module 12 is electrically or wirelessly connected to the image comparison module 13, and the image comparison module 13 is electrically or wirelessly connected to the energy loss calculation module 14, where functions of each module are described as follows:

the photographing module 11 is used for photographing an accident vehicle and uploading a photo to the three-dimensional modeling module 12, it should be noted that the photographing module 11 may be a gropor camera, a handheld three-dimensional photographing scanner, or a camera with other modes, and when the handheld three-dimensional photographing scanner is used, the three-dimensional modeling module is integrated.

The three-dimensional modeling module 12 builds a three-dimensional model of the vehicle according to the shot vehicle picture, and may adopt other existing modeling software capable of realizing the function, such as T-profiles software, 3DF Zephyr software, Solidworks software, and the like.

The image comparison module 13 compares the three-dimensional model of the accident vehicle with the three-dimensional model of the vehicle with a good model of the accident vehicle, and determines the area deformed by the collision and the deformation thereof, it should be noted that after the three-dimensional model is established, the three-dimensional model is led into the image comparison module 13 for comparison, the image comparison module 13 may be a common image comparison identification module used in python software or a common image comparison identification module used in MATLAB software, and the two software can compare different photos and directly output the change ratios of different parts in the photos, i.e. inherit the common image comparison identification module 14, and certainly can also be software in other forms for realizing the image comparison function.

The energy loss calculation module 14 can calculate the energy loss caused by collision deformation according to the deformed region, the deformation amount of the deformed region, and the stiffness coefficient stored in the database, and it should be noted that a server, a single chip microcomputer, a PLC controller, a processor, or other devices capable of implementing the function may be used as a program carrier of the collision energy fast calculation method, and the specific models of the devices may be selected according to the requirements of the required calculation capacity, calculation time, and the like.

It should be noted that, the user end 1 is convenient for the user to carry and use, the photographing module 11 can use a camera on the mobile phone of the user, an algorithm for realizing three-dimensional modeling, image comparison and energy loss calculation functions is written on a mobile phone APP, the program software is given with the authority to obtain the mobile phone photo, and the carrier for running the program software can be a chip or a processor in the mobile phone, so that the user can directly use the program software only by downloading the software of the user end 1, and the use is convenient.

Data are interacted between the database 3 and the user side 1, three-dimensional models of vehicles of different types and rigidity coefficients of all cell units are stored in the database 3, and the database 3 can be a self-built server or an existing cloud database is adopted.

In a more preferred embodiment, the system for rapidly calculating the vehicle deformation collision energy in the traffic accident further includes a management terminal 2, the management terminal 2 includes a stiffness coefficient calculation module 21, a statistical analysis module 22 and a classification query module 23, the stiffness coefficient calculation module 21 is electrically or wirelessly connected with the statistical analysis module 22, the statistical analysis module 22 is electrically or wirelessly connected with the classification query module 23, and functions of each module are described as follows:

the rigidity coefficient calculation module 21 can calculate the rigidity coefficient of the cell unit according to the energy loss caused by collision deformation, store the calculated rigidity coefficient into the database 3 according to the type of the vehicle, and continuously update the rigidity coefficient of the vehicle cell unit corresponding to the database 3; it should be noted that a server, a single chip, a PLC controller, a processor, or other devices capable of implementing the function may be used as a program carrier of the stiffness coefficient calculation method, and specific models of these devices may be selected according to requirements such as required calculation capacity and calculation time.

The statistical analysis module 22 can analyze safe driving speeds, vehicle easily damaged parts, vehicle collision-resistant parts and the like of different vehicles according to user requirements; the classification query module 23 can query the stiffness coefficients of different vehicles and different parts according to the user requirements; and data are interacted between the management terminal 2 and the user terminal 1 and between the management terminal and the database 3.

It should be noted that the management terminal 2 is mainly used by an operator manager, and for convenience of use, the algorithm for implementing the functions of rigidity coefficient calculation, statistical analysis and classified query can be implemented by a mobile phone APP, a web page, an independently configured server or other manners.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various changes, modifications, alterations, and substitutions which may be made by those skilled in the art without departing from the spirit of the present invention shall fall within the protection scope defined by the claims of the present invention.

Claims (9)

1. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident is characterized by comprising the following steps: selecting a known accident vehicle, calculating energy lost due to deformation in the collision process according to the vehicle speed before collision and the vehicle speed after collision, dividing the known accident vehicle into a plurality of continuous cell units, measuring the number of the deformed cell units and the corresponding deformation amount, taking the lost energy as a training sample, and calculating the rigidity coefficient of the deformed cell units by utilizing a CNN convolutional neural network algorithm; selecting a plurality of accident vehicles of the same type, and training for a plurality of times until the rigidity coefficients of all the cell units are calculated; and when collision actually occurs, calculating the energy loss caused by deformation according to the number of the deformed cell units and the corresponding rigidity coefficients.

2. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident according to claim 1, wherein: comprises the following steps of (a) carrying out,

a1, selecting the known accident vehicle according to the speed v before the accident vehicle collides₁Post-collision velocity v₂Calculating the energy loss E of the deformation occurring during the collision₀；

A2, establishing a three-dimensional model of the accident vehicle, dividing the accident vehicle into n continuous cell units in a three-dimensional space, and recording the rigidity coefficient of each cell unit as C₁、C₂、C₃……C_n-1、C_n；

A3, measuring the number a of deformed cell units in the deformed area of the accident vehicle and the corresponding deformation amount b of each deformed cell unit, and marking the cell units in a three-dimensional model;

a4, loss of energy E₀As a training sample, the stiffness coefficient C is set_nAs an output result, calculating the rigidity coefficient C of each deformed cell unit by using a CNN convolutional neural network algorithm_n；

A5, selecting a plurality of accident vehicles of the same type, repeating the steps A1-A4 for a plurality of times of training, and obtaining the rigidity coefficient C of each cell unit of the accident vehicles_n；

A6, the number a of cells that deform in response to the vehicle in the actual collision, and the corresponding stiffness coefficient C_nCalculating the loss energy E₀。

3. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident according to claim 2, wherein: in the step a3, the deformation amount b is a ratio of cell unit deformation, and b ═ V is calculated₀-V)/V₀*100％，V₀Is the volume of the cell unit before deformation, and V is the volume of the cell unit after deformation.

4. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident according to claim 2, wherein: in the step a3, the deformation amount b is a ratio of cell unit deformation, and 4 grades are set, which are 25%, 50%, 75%, and 100%, respectively.

5. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident according to claim 2, wherein: in the step A1-A6, the cell units are of a regular hexahedron type.

6. The method for rapidly calculating the vehicle deformation collision energy in the traffic accident according to claim 2, wherein: in the step a5, the energy loss E caused by the deformation of the same type of vehicle is classified according to the type of vehicle, the actual vehicle weight of the vehicle, the vehicle wheel base, the vehicle driving style and the vehicle power source₀The calculation is performed as a training sample of the same group.

7. Vehicle deformation collision energy rapid calculation system in traffic accident, its characterized in that: the energy loss control system comprises a user side (1) and a database (3), wherein the user side (1) comprises a photographing module (11), a three-dimensional modeling module (12), an image comparison module (13) and an energy loss calculation module (14), the photographing module (11) is used for photographing an accident vehicle and uploading the photograph to the three-dimensional modeling module (12), the three-dimensional modeling module (12) establishes a vehicle three-dimensional model according to the vehicle photograph, the image comparison module (13) compares the accident vehicle three-dimensional model with a vehicle three-dimensional model of a vehicle with the model vehicle, and determines a region deformed due to collision and the deformation thereof, and the energy loss calculation module (14) can calculate the energy loss caused by collision deformation according to the deformed region and the deformation thereof and a rigidity coefficient stored in the database (3); and data are interacted between the database (3) and the user side (1).

8. The system for rapidly calculating the deformation collision energy of the vehicle in the traffic accident according to claim 7, wherein: three-dimensional models of vehicles of different types and rigidity coefficients of all cell units are stored in the database (3).

9. The system for rapidly calculating vehicle deformation collision energy in a traffic accident according to any one of claims 7 and 8, characterized in that: the vehicle cell unit stiffness analysis system is characterized by further comprising a management end (2), wherein the management end (2) comprises a stiffness coefficient calculation module (21), a statistical analysis module (22) and a classification query module (23), the stiffness coefficient calculation module (21) can calculate the stiffness coefficient of a cell unit according to energy loss caused by collision deformation, the calculated stiffness coefficient is stored in the database (3) according to the type of a vehicle, and the stiffness coefficient of the corresponding vehicle cell unit in the database (3) is continuously updated; the statistical analysis module (22) can analyze safe driving speeds, vehicle easily damaged parts, vehicle collision-resistant parts and the like of different vehicles according to user requirements; the classification query module (23) can query the rigidity coefficients of different vehicles and different parts according to the user requirements; and data are interacted among the management end (2), the user end (1) and the database (3).

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