CN204730814U - A kind of parts passer based on line laser three-dimensional measurement - Google Patents

Abstract

The utility model discloses a kind of parts passer based on line laser three-dimensional measurement, comprise the mobile platform being arranged on and guide rail at the uniform velocity can slide along guide rail, mobile platform is fixed parts to be measured, have video camera by support installing above described guide rail and several are for the generating laser to the equidistant linear striped of parts to be measured projection; Described camera acquisition generating laser projects to component surface to be measured and the image be out of shape after surface modulation, and the image data transmission collected is carried out analyzing and processing to computing machine by video camera.The utility model projects component surface to be measured by the linear striped sent by generating laser and carries out linear sweep, utilize the image information on video camera continuous acquisition parts to be measured, the three-dimensional picture of measured three dimensional point cloud and initial designs is analyzed under the same coordinate system, thus qualified parts are screened, accuracy of detection is high, can realize robotization, production line balance.

Description

A kind of parts passer based on line laser three-dimensional measurement

Technical field

The utility model belongs to three dimensional optical measuring and parts quality testing field, is specifically related to a kind of parts passer based on line laser three-dimensional measurement.

Background technology

Along with the fast development of machinery manufacturing industry, the quality control of many manufacturing industry to its process component proposes more and more higher requirement.But current most enterprises does good not due to the problem such as technology, cost in parts quality testing.When component inspection, a kind of is the method using sensation inspection, namely reviewer to only rely on by means of visual senses such as vision, hearing, touch feels basic without inspection machine to check the method for part technology status.This method is easy, expense is low, but this method can not carry out quantitative testing, can not be used for the part that testing accuracy requirement is higher, and requires that reviewer has rich experience.Another kind is instrument, inspection of tools method, namely uses the method that some measurer, mechanical devices etc. are tested to part.In a word, quality testing is usually rule of thumb selected suitable measurer by master worker, is determined that rational measuring method is carried out measurement and detected, and so not only measuring speed is slow, measuring accuracy also cannot ensure.In addition, for large quantities of parts, can not all measure, can only randomly draw parts thereof and measure, then estimate overall quality condition with the quality condition of parts in sample drawn, quality testing effect is poor.Sum up the existing method that auto parts and components are detected, have the following disadvantages: 1) parts quality inspection needs artificial intervention, and automaticity is not high, and efficiency is lower.2) rely on master worker's measurer and experience to detect, uncertain factor is comparatively large, and testing accuracy is lower.3) anti-interference is more weak, measurement is unstable.

Utility model content

The purpose of this utility model is for above-mentioned the problems of the prior art, a kind of parts passer based on line laser three-dimensional measurement is provided, in auto parts and components quality testing process, can under the prerequisite guaranteeing accuracy of detection and efficiency, do not need artificial intervention, realize robotization, production line balance, enhance productivity, reduce production cost.

To achieve these goals, the technical solution adopted in the utility model is:

Comprise the mobile platform being arranged on and guide rail at the uniform velocity can slide along guide rail, mobile platform is fixed parts to be measured, have video camera by support installing above described guide rail and several are for the generating laser to the equidistant linear striped of parts to be measured projection; Described camera acquisition generating laser projects to component surface to be measured and the image be out of shape after surface modulation, and the image data transmission collected is carried out analyzing and processing to computing machine by video camera.

Described generating laser adopts six generating lasers linearly equidistantly arranged.

Video camera is parallel with the mobile platform upper surface not placing parts to be measured with the photocentre line of generating laser.

Regulate generating laser and video camera by the scaling board being placed in mobile platform central authorities, make that light is complete to be projected scaling board and guarantee that shooting function photographs complete light.

Described scaling board adopts the black and white grate of 500mm × 500mm, and each black and white grid is of a size of 10mm × 10mm, and a drift angle of black and white grate is provided with initial point for demarcating as bearing point.

Described video camera is CCD camera.

Compared with prior art, the beneficial effect that has of the utility model is as follows:

1) the utility model is for parts Design of Production Line, can realize automatically carrying out quality testing in parts production run, and can be screened by qualified part rapidly, improves the detection efficiency of parts;

2) the utility model generating laser and video camera maintain static, and parts to be measured move with mobile platform, only need demarcate an optical plane, and demarcate comparatively simple, data redundancy is few, and work efficiency is higher;

3) the utility model uses laser transmitter projects light, camera acquisition image, and quality inspection precision is high;

4) the utility model does not need to keep gauge head and parts geo-stationary to be measured in measuring process, insensitive to vibrating, anti-interference and stability better.

Accompanying drawing explanation

Fig. 1 the utility model parts quality inspection platform structure figure;

The structural representation of Fig. 2 the utility model laser three-D rapid measurement device;

The Line Chart through body surface modulation distortion that Fig. 3 the utility model camera acquisition arrives;

The schematic diagram of Fig. 4 the utility model triangulation;

Fig. 5 the utility model black and white grid demarcates version schematic diagram;

The workflow diagram of Fig. 6 the utility model measuring method;

In accompanying drawing: 1-guide rail; 2-mobile platform; 3-support; 4-video camera; 5-generating laser; 6-scaling board.

Embodiment

Below in conjunction with accompanying drawing, the utility model is described in further detail.

See Fig. 1, the utility model, based on the parts passer of line laser three-dimensional measurement, comprises generating laser 5, video camera 4, guide rail 1, mobile platform 2, support 3, scaling board 6 and computing machine;

Generating laser 5, adopt the generating laser 5 of six straight line, adjacent two spacing are H, for projecting the linear striped of six equidistant H to parts to be measured; Video camera 4 i.e. high-speed CCD camera, arranges with six generating laser 5 conllinear, projects to surface of automobile part to be measured for gathering generating laser 5, and the image be out of shape after surface modulation; Computer picture signal input part is connected with the image signal output end of CCD camera, for the graphical information that analyzing and processing video camera obtains; Guide rail 1, for installing mobile platform 2, at the uniform velocity being moved with specific speed by the mobile platform 2 controlled on guide rail, being convenient to line laser and scanning parts to be measured; Mobile platform 2, for placing parts to be measured, controls its translational speed by computing machine; Support 3, for installing generating laser 5 and video camera 4, and can regulate the height of generating laser 5 and video camera 4; Scaling board 6, for the parameter of video camera 4 and light source in calibration measurements system.

The utility model based on the parts passer principle of work of line laser three-dimensional measurement is:

In the utility model, the linear striped that generating laser 5 sends is projected component surface to be measured, formed by component surface shape institute to be measured modulating three-dimensional optical strip image on surface, then the mobile platform 3 of parts to be measured is loaded with setting speed uniform motion by control, linear sweep is carried out to component surface to be measured, utilize the image information on CCD camera continuous acquisition parts to be measured, and passed to computing machine and carry out analyzing and processing, obtain the three dimensional point cloud of parts to be measured under world coordinate system.Non-uniform rational B-spline is utilized by three dimensional point cloud to construct smooth curved surface, the three-dimensional picture of measured three dimensional point cloud and initial designs is analyzed under the same coordinate system, judge maximum error whether within the scope of the limits of error, if in the allowed band that it is arranged, then qualified parts are screened by sorting mechanism.

See Fig. 6, the utility model is based on the parts quality determining method of line laser three-dimensional measurement, and concrete implementation step is as follows:

(1) the black and white grate of 500mm*500mm is adopted to demarcate measuring system, as shown in Figure 5, wherein black and white grid is of a size of 10mm*10mm, the light that the position of adjustment scaling board 6 makes six generating lasers 5 send can project on scaling board 6, and regulate video camera 4 at different positions shooting scaling board 6, during shooting, ensure that laser rays is incident upon scaling board 6 central area.Then, under the picture determination world coordinate system collected by the black and white grid and video camera 4 that scaling board 6 are of a size of 10mm*10mm, in X, Y-direction, 10mm correspondence to collect on image N on respective direction coordinate _xi, N _yipixel, final six generating lasers 5 linear striped projected on scaling board 6 determines that X, Y-direction are tied to the conversion coefficient K of world coordinate system from pixel coordinate _xi, K _yi, i=1,2,3,4,5,6; World coordinate system conversion coefficient K is tied to from pixel coordinate _xi, K _yi, i=1,2,3,4,5,6, is obtained by following 3 computing formula:

[x _cy _cz _c] ^T＝T+R[x y z] ^T(1)

$\begin{array}{cc}\stackrel{\·}{x}=d\frac{xc}{zc}& \stackrel{\·}{y}=d\frac{yc}{zc}\end{array}---\left(2\right)$

$\begin{array}{cc}u=n_{xi}\×\stackrel{\·}{x}+U_0& v=n_{yi}\×\stackrel{\·}{y}+V_0---\end{array}\left(3\right)$

Wherein: (x, y, z) is coordinate in world coordinate system, (x _c, y _c, z _c) be coordinate in camera coordinate system, rotation matrix is R, and translation matrix is T, and the coordinate of image coordinate system corresponding point is focal length of camera is d, and (u, v) is ranks coordinate figure corresponding in image coordinate system, (U ₀, V ₀) be the coordinate of image coordinate system initial point in pixel coordinate system.N _xi, n _yifor the pixel count in horizontal and vertical direction unit distance in image coordinate system, that is: n _xi=N _xi/ 10, n _yi=N _yi/ 10, i=1,2,3,4,5,6.Rotation matrix R and the concrete representation of translation matrix T are:

$\begin{array}{cc}R=\left[\begin{array}{ccc}{r}_{11}& r_{12}& r_{13}\\ r_{21}& r_{22}& r_{23}\\ r_{31}& r_{32}& r_{33}\end{array}\right]& T=\left[\begin{array}{c}{t}_x\\ t_y\\ t_z\end{array}\right]\end{array}---\left(4\right)$

Therefore, be tied to the conversion formula of camera coordinate system from world coordinates, namely formula (1) can specifically be expressed as:

$\left[\begin{array}{c}{x}_c\\ y_c\\ z_c\end{array}\right]=\left[\begin{array}{ccc}{r}_{11}& r_{12}& r_{13}\\ r_{21}& r_{22}& r_{23}\\ r_{31}& r_{32}& r_{33}\end{array}\right]\left[\begin{array}{c}x\\ y\\ z\end{array}\right]+\left[\begin{array}{c}{x}_t\\ y_t\\ z_t\end{array}\right]---\left(5\right)$

(2) the linear striped that generating laser 5 sends is projected component surface to be measured, as shown in Figure 2;

(3) at the uniform velocity move by controlling mobile platform 2, the linear striped that laser generator 5 is sent carries out linear sweep to component surface to be measured on mobile platform 2;

(4) utilize CCD camera to gather the image information of component surface to be measured, obtain the striped L after surface modulation ₁~ L ₆, as shown in Figure 3.The image information of CCD camera collection input computing machine is carried out Treatment Analysis.

(5) from the image information gathered, parts height value to be measured is obtained according to principle of triangulation.Coupling system calibrating parameters obtains the corresponding relation of pixel coordinate and parts world coordinates to be measured on picture again.When the light that generating laser 5 sends projects reference planes, have part light and reflect, light scioptics imaging display on photosurface of reflection.When tested parts are placed in reference planes, the pixel position of display can change, and this variable quantity reflects parts height change.As shown in Figure 4, the height value h of tested parts, that is, the computing formula of the Z coordinate of tested parts in world coordinate system is:

$\frac{\stackrel{\‾}{B_{1}D}}{\stackrel{\‾}{BE}}=\frac{CD}{CE}=\frac{l_2-\stackrel{\‾}{{\mathrm{DA}}_1}}{l_1+\stackrel{\‾}{AE}}---\left(6\right)$

Wherein $\stackrel{\‾}{B_{1}D}=xsin\mathrm{\β},\stackrel{\‾}{BE}=\stackrel{\‾}{BA}sin(\mathrm{\α}+\mathrm{\θ}),\stackrel{\‾}{{\mathrm{DA}}_1}=xcos\mathrm{\β},\stackrel{\‾}{AE}=\stackrel{\‾}{BA}cos(\mathrm{\α}+\mathrm{\θ}),\stackrel{\‾}{BA}=\frac{h}{cos\mathrm{\θ}}.$

Lens imaging computing formula is:

$\frac{1}{u}+\frac{1}{v}=\frac{1}{f}---\left(7\right)$

Wherein, object distance is u, and image distance is v, and focal length is f.When incident luminous point is on parts to be measured, u=l ₁, v=l ₂, therefore, the computing formula of tested parts height h is:

Wherein, parameter l after light path is determined ₁, l ₂, α, β, θ, f are known, know the displacement x on photosensitive unit, just can determine the height h of parts to be measured.Get "-" when physical plane is under reference planes, get "+" time on the reference plane.

(6) three dimensional point cloud of acquisition is carried out flying spot rejecting, some cloud and fusion treatment, obtain the three dimensional point cloud that parts to be measured are complete.According to range deviation E (p _i) carrying out flying spot rejecting with comparing of given threshold value E, its algorithmic formula is:

$E\left(p_i\right)=\sqrt{\underset{j=1}{\overset{k}{\Σ}}{(||p_i-c_j||-\frac{1}{k}\underset{j=1}{\overset{k}{\Σ}}||p_i-c_j||)}^2}---\left(9\right)$

Wherein, p _ibe any point in cloud data, k is point of proximity number, c _jp _iin some k neighborhood a bit (j=1 ..., k), if some p _irange deviation E (p _i) be greater than given threshold value E, then this point is considered as flying spot, and is rejected, otherwise retained.

Moving least squares surfaces is utilized to carry out to the some cloud P and Q overlapping region that need splicing 2 curved surface P (u that matching obtains, v) with Q (u, v), and initial corresponding point set is determined, then remove wrong corresponding point set according to curvature limitation, determine final corresponding point set.Calculate the some p obtained in some cloud P _inormal vector N _pi, it meets at q in normal vector direction and some cloud Q _ipoint, then to overlap point p _ipoint and q _ipoint does so average that newly to put cloud d _i, final splicing is fused to a complete model.

(7) utilize non-uniform rational B-spline (NURBS) that measured three dimensional point cloud process is constructed smooth curved surface in a computer.The formula being constructed smooth surface by three dimensional point cloud is:

$P(x,y)=\frac{\underset{i=0}{\overset{m}{\Σ}}\underset{j=0}{\overset{n}{\Σ}}{w}_{i,j}{p}_{i,j}{N}_{i,p}\left(x\right)N_{i,p}\left(y\right)}{\underset{i=0}{\overset{m}{\Σ}}\underset{j=0}{\overset{n}{\Σ}}{w}_{i,j}{N}_{i,p}\left(x\right)N_{j,p}\left(y\right)}---\left(10\right)$

Wherein: p _i,j(i=0,1 ..., m; J=0,1 ..., n) be control vertex, it is topological matrix form, forms a control mesh; w _i,jfor with summit p _i,jcorresponding weights; N _i,p(x) and N _j,py () is respectively the specification B-spline basis function of parameter x to p time and parameter y to q time, they be by x to y to knot vector U=(x ₀, x ₁..., x _m-p+1) and V=(y ₀, y ₁..., y _n-q+1) determine by deBoor-Cox recursion formula.

N _i,px the recursion formula of () is:

$\left\{\begin{array}{c}{N}_{i,0}\left(x\right)=\left\{\begin{array}{c}1,x_i\≤x\≤x_{i+1}\\ 0,x\≥x_{i+1}\end{array}\right.\\ N_{i,p}\left(x\right)=\frac{x-x_i}{x_{i+p}-x_i}{N}_{i,p-1}\left(x\right)+\frac{N_{i,p+1}\left(x\right)-x}{N_{i,p+1}\left(x\right)-x_{i+1}}{N}_{i+1,p-1}\left(x\right)\end{array}\right.---\left(11\right)$

Wherein, 0/0=0 is specified.N _j,py recursion formula and the above formula of () are similar.

(8) three-dimensional model measuring parts the three-dimensional model to be measured and initial designs obtained is analyzed under the same coordinate system, obtains maximum error E _max, its computing formula is:

E _max＝|M ₂-M ₁| (12)

Wherein, M ₁for design load, M ₂for measured value.

(9) parts to be measured error nephogram is everywhere shown in a computer according to each point maximum error, judge maximum error whether within the scope of the limits of error, if in the allowed band that it is arranged, then by sorting mechanism, qualified parts are screened, if error is excessive, then on rejected part, mark maximum error position.

Claims (6)

1. the parts passer based on line laser three-dimensional measurement, it is characterized in that: comprise the mobile platform (2) being arranged on and guide rail (1) at the uniform velocity can slide along guide rail (1), the upper fixing parts to be measured of mobile platform (2), described guide rail (1) top is provided with video camera (4) by support (3) and several are for projecting the generating laser (5) of equidistantly linear striped to parts to be measured; Described video camera (4) gathers generating laser and projects to component surface to be measured and the image be out of shape after surface modulation, and the image data transmission collected is carried out analyzing and processing to computing machine by video camera (4).

2. the parts passer based on line laser three-dimensional measurement according to claim 1, is characterized in that: described generating laser (5) adopts six generating lasers linearly equidistantly arranged.

3. the parts passer based on line laser three-dimensional measurement according to claim 1, is characterized in that: video camera (4) is parallel with mobile platform (2) upper surface not placing parts to be measured with the photocentre line of generating laser (5).

4. the parts passer based on line laser three-dimensional measurement according to claim 1, it is characterized in that: regulate generating laser (5) and video camera (4) by the scaling board (6) being placed in mobile platform (2) central authorities, make that light is complete projects scaling board (6) and function of guaranteeing to make a video recording photographs complete light.

5. the parts passer based on line laser three-dimensional measurement according to claim 4, it is characterized in that: described scaling board (6) adopts the black and white grate of 500mm × 500mm, each black and white grid is of a size of 10mm × 10mm, and a drift angle of black and white grate is provided with initial point for demarcating as bearing point.

6. the parts passer based on line laser three-dimensional measurement according to claim 1 or 4, is characterized in that: described video camera (4) is CCD camera.