CN203917192U - A kind of spherome surface quality detection device - Google Patents

Abstract

The utility model discloses a kind of spherome surface quality detection device, described spherome surface quality detection device comprises automatic charging machine, rhythm control mechanism, generating mechanism, vision system, sorting system, before described rhythm control mechanism is positioned at the end and generating mechanism of automatic charging machine, control spheroid to be measured and enter one by one described generating mechanism, described rhythm control mechanism comprises two groups of blocking mechanisms, described two groups of blocking mechanisms in turn movable control spheroid to be measured advancing and mobile.The feeding beat of this spherome surface quality detection device is controlled, can reduce the interference between spheroid to be measured, and generating motion is simultaneously comprehensive, to the loss of spheroid to be measured, is down to minimum.

Description

A kind of spherome surface quality detection device

Technical field

The utility model relates to defects detection field.Particularly design a kind of automatic ball surface defect detecting device based on vision.Detected spheroid is the spheroid of steel ball, Ceramic Balls, baton round, the especially ball bearing of non-polishing or polishing.

Background technology

Bearing has irreplaceable effect in modern industry, and the quality intuition of steel ball is determining precision, performance, the service life of bearing.According to bearing net, add up: the problem that steel ball causes accounts for 85% of bearing problem, steel ball causes the ratio of bearing failure up to 78%, far above external 30%, wherein 65% by steel ball surface quality, is caused.

At present, the most of detection method adopting of domestic steel ball manufacturing enterprise is traditional lamp inspection, and personnel stir the steel ball in grafter with hand, and naked eyes under light (or low power magnifying glass) are observed, and pick out by hand defect ball.In the face of detection demand in batch, not only detection efficiency is low but also manual push and block cannot guarantee to launch completely ball surface for lamp test, and easily undetected or flase drop, simultaneously very big to operating personnel's eye injury.Development along with the detection technique of defect, as eddy current inspection technology, ultrasonic examination technology, photoelectric detecting technology and vision detection technology etc., developed steel ball surface defect checkout equipment both at home and abroad, as bearing steel ball photoelectricity appearance detecting instrument, U.S.'s bearing steel ball eddy current flaw detec of the eddy current testing instrument of Czech, Japan.It is few that these equipment exist a kind of equipment to adapt to steel ball kind, is prone to undetected and erroneous judgement, and the problem such as equipment price costliness, in being unfavorable for producing, promotes the use of again.

The patent No. is that the Chinese utility model patent of ZL200310109912.4 discloses a kind of steel ball surface defect detection method based on vision, the ring through hole that distributes on feed shelter rotates with a certain speed as test chamber carrying steel ball, steel ball below is launched pan arrest by another and is lived, expansion dish is done eccentric rotary and is driven steel ball rotation to realize steel ball expansion, and expanding unit is placed in kerosene.CCD collected by camera steel ball surface image directly over test chamber, computer provides evaluation result by identifying its blemish, manually controls sorting.The expanding unit of the method is complicated, and launches to have randomness, can not guarantee that sphere launches completely; Immersion liquid causes necessarily stained to steel ball self, gather image and easily have impurity and affect judge, not only needs periodic replacement, and increases follow-up cleaning step; Detecting ball scope is big-and-middle-sized steel ball, is not suitable for the miniature iron shot below 3mm.The patent No. is that the Chinese utility model patent of ZL200910040283.1 has developed vision bead defect detection equipment and method for miniature iron shot, but the ball unfolded surface of its detecting position take that not producing slides as prerequisite still relies on pallet to its bottom rubbing, can not guarantee to be in full swing; Sorting mechanism adopts magnetic mode to reject defect ball and easily causes steel ball magnetization, follow-uply also needs to increase demagnetization step; Sorting mechanism is complicated, and detection efficiency is low.Number of patent application is: 201210134454.9 and Patents propose to adopt vibrating disc material loading, the transmission of V-type groove guide rail, two vision-based detection, start the steel ball surface defect detection apparatus sorting, but that exists feeding uncontrollable, detect the not fixing large precision lampet in visual identity visual field problem of steel ball position.

In view of this, the utility model proposes a kind of full-automation with automatic control material loading beat, original position generating motion, automatic sorting, without consumable accessory, efficient spherical surface defect checkout gear.

Utility model content

For prior art above shortcomings, the problem that the utility model solves is: provide a kind of material loading beat controlled, while detecting to the loss-free spherical surface defect detection method of spheroid to be measured.

A kind of spherome surface quality detection device, comprise automatic charging machine, rhythm control mechanism, generating mechanism, vision system, sorting system, before described rhythm control mechanism is positioned at the end and generating mechanism of automatic charging machine, control spheroid to be measured and enter one by one described generating mechanism, described rhythm control mechanism comprises two groups of blocking mechanisms, described two groups of blocking mechanisms in turn movable control spheroid to be measured advancing and mobile.

Preferably, described rhythm control mechanism is comprised of the first blocking mechanism and the second blocking mechanism and first groove, described the first blocking mechanism comprises the first cylinder, the first connector, the first spiral inching device and the first gear pin, described the second blocking mechanism comprises the second cylinder, the second connector, the second spiral inching device and the second gear pin, wherein said first, the second cylinder is fixed on floor, described first, the second spiral inching device is connected to described first, the upper end of the second cylinder, described first, the second spiral inching device and described first, the second gear pin is respectively by described first, the second connector connects.

Preferably, described the first gear pin and second keeps off 1～1.5 times that the distance between pin is sphere diameter to be measured.

Preferably, the output guide rail of described automatic charging machine is V-type, and this output guide rail has the inclination of 1 °～5 °.

Preferably, described generating mechanism is comprised of source of the gas, some valves, the second groove, the 3rd cylinder, a Z-type connector, a position control and a baffle plate, wherein said valve is connected with described source of the gas and is opened on described the second groove, described position control is fixed on floor, the output of position control is connected with described the 3rd cylinder, described the 3rd cylinder is connected with described baffle plate by described Z-type connector and drives baffle plate to move up and down, and described baffle plate position is perpendicular in described the second groove.

Preferably, described valve comprises bottom valve and sidewall valve, described bottom valve is opened in the bottom of described the second groove, and described sidewall valve is opened on the both sides cell wall of the second groove, and the axle center of described sidewall valve and described the second groove form the angle of 10～80 °.

Preferably, described vision system comprises some light sources and a taper cover, described taper cover is positioned at the top of described generating mechanism, and described light source is arranged on the inside of described taper cover, on described taper cover, according to the position of visual effect, offers a plurality of detections hole.

Preferably, described vision system further comprises camera, camera lens, for portal frame and the DPA data processing activity of fixed camera, described camera angle capable of regulating, and described camera quantity is consistent with the quantity in described detection hole.

Preferably, described camera quantity is 3, comprising: first camera, second camera and third phase machine, the angle between described first camera and second camera, second camera and third phase machine is 60 °.

Preferably, described sorting system comprises oscillating cylinder, pendulum, sub-material guide rail and magazine, described pendulum is positioned at the porch of sub-material guide rail, described oscillating cylinder is fixed on floor, the output of oscillating cylinder is connected with described pendulum through described sub-material guide rail, described magazine is positioned at the exit of described sub-material guide rail, and magazine quantity is consistent with the export volume of sub-material guide rail.

Compared with prior art, the utlity model has following advantage:

(1) feeding beat can be controlled, and reduces the interference between spheroid to be measured, while guaranteeing each detection, only has a spheroid to be measured to pass through;

(2) supply gas and make spheroid to be measured do original position to rotatablely move, guarantee that spheroid generate is comprehensively complete, improve the accuracy detecting;

(3) size of difference spheroid to be measured is had to stronger adaptability;

(4) whole testing process can not produce loss to spheroid to be measured;

(5) testing process is full-automatic, reduces the requirement to operating personnel, improves accuracy of detection and the degree of accuracy.

Accompanying drawing explanation

For the technical scheme in the utility model embodiment is more clearly described, to the accompanying drawing of required use in embodiment be introduced simply below, apparently, the accompanying drawing the following describes is only some embodiment that record in the utility model, for those of ordinary skills, do not paying under the prerequisite of creative work, can also obtain according to these accompanying drawings other accompanying drawing.

Fig. 1 is the overall structure schematic diagram of spherome surface quality detection device;

Fig. 2 is the structural representation of rhythm control mechanism in the utility model embodiment;

Fig. 3 is the structural representation of generating mechanism in the utility model embodiment;

Fig. 4 is the structure for amplifying schematic diagram of A part in Fig. 3;

Fig. 5 is camera setting position and effect schematic diagram in vision system in the utility model embodiment;

Fig. 6 is the structural representation of vision system in the utility model embodiment;

Fig. 7 is the structural representation of sorting system in the utility model embodiment;

Fig. 8 is the structure for amplifying schematic diagram of B part in Fig. 7.

Fig. 9 is the detecting step of this spherome surface quality detection device.

Wherein:

1, automatic charging machine;

2, rhythm control mechanism; 21, the first groove; 221 first cylinders; 222, the second cylinder; 231, the first connector; 232, the second connector; 241, the first spiral inching device; 242, the second spiral inching device; 251, the first gear pin; 252, the second gear pin;

3, generating mechanism; 31, the second groove; 32, the 3rd cylinder; 33, Z-type connector; 34, position control; 35, baffle plate; 361, bottom valve; 362, sidewall valve;

4, vision system; 41, taper cover; 42, portal frame; 43, camera; 431, first camera; 432, second camera; 433, third phase machine;

5, sorting system; 51, oscillating cylinder; 52, sub-material guide rail; 53, magazine.

The specific embodiment

To the technical solution of the utility model, be clearly and completely described by the specific embodiment below.Obviously, described embodiment is only the utility model part embodiment, rather than whole embodiment.Embodiment based in the utility model, those of ordinary skills are not making the every other embodiment obtaining under creative work prerequisite, all belong to the scope of the utility model protection.

Traditional detection mode cannot be taken into account the expansion completely of sphere and spheroid to be measured without stained, and material loading is uncontrollable.The utility model is for deficiency of the prior art, a kind of spherome surface quality detection device is provided, this spherome surface quality detection device comprises automatic charging machine 1, rhythm control mechanism 2, generating mechanism 3, vision system 4, sorting system 5, before wherein rhythm control mechanism 2 is positioned at the end and generating mechanism 3 of automatic charging machine 1, in described generating mechanism 3, be provided with the valve of source of the gas and some different azimuth, from the air-flow of described valve ejection, spheroid is blown afloat and is made spheroid do original position rotation, described vision system 4 is positioned at the top of described generating mechanism 3, described sorting system 5 is positioned at the end of described generating mechanism 3.

As shown in Figure 1, the output guide rail of above-mentioned automatic charging machine 1 is V-type, and this output guide rail has the inclination of 1～5 °, makes spheroid to be measured can rely on self gravitation to continue to slide forward.

As shown in Figures 1 and 2, above-mentioned rhythm control mechanism 2 is comprised of the first blocking mechanism and the second blocking mechanism and first groove 21.Wherein the first blocking mechanism comprises the first cylinder 221, the first connector 231, the first spiral inching device 241 and the first gear pin 251; The second blocking mechanism comprises the second cylinder 222, the second connector 232, the second spiral inching device 242 and the second gear pin 252.Above-mentioned the first cylinder 221 and the second cylinder 222 are fixed on floor, the first spiral inching device 241 is positioned at the upper end of the first cylinder 221, the second spiral inching device 242 is positioned at the upper end of the second cylinder 222, and the first cylinder 221 and the second cylinder 222 will promote respectively the first spiral inching device 241 and the second spiral inching device 242 moves up and down.Between above-mentioned the first spiral inching device 241 and the first gear pin 251, by the first connector 231, connect, in like manner 252 of the second spiral inching device 242 and the second gear pin are connected by the second connector 232, and two spiral inching devices can drive the gear pin of both correspondences to do the fine setting of front and back position.Distance between described the first gear pin 251 and the second gear pin 252 is less than 1～1.5 times of sphere diameter to be measured, and preferably, the distance between the first gear pin 251 and the second gear pin 252 is the diameter of a spheroid to be measured.This rhythm control structure is when work, the second gear pin 252 first rises and blocks spheroid to be measured, then the first gear pin 251 rises, because the distance between two gear pins is the diameter of a spheroid to be measured, therefore the first gear pin 251 will fit tightly spheroid to be measured after rising, and the first gear pin 251 will stop that rear enters the next one spheroid to be measured of rhythm control mechanism 2 from automatic charging machine 1 simultaneously.Then the second gear pin 252 declines, spheroid to be measured is released, after discharging, the second gear pin 252 rises again, the first gear pin 251 declines and discharges next spheroid to be measured to before the second gear pin 252, after spheroid to be measured puts in place, the first gear pin 251 rises again, so repeatedly realizes discharging by rhythm control of spheroid to be measured.By the first gear pin 251 and the second gear, the distance between pin 252 is designed to 1～1.5 times of sphere diameter to be measured, and this distance can effectively guarantee to enter two spheroids to be measured between gear pin at every turn and only have one, to realize the object of control beat.Wherein the first groove is a kind of in U-shaped, V-type, the various shape such as trapezoidal, and the utility model embodiment is preferably V-type groove, because the contact area of V-type groove and spheroid to be measured is minimum, the loss of power and inertia is also minimum.And U-shaped groove, dovetail groove also can adopt under the prerequisite that does not affect the utility model testing result, so the utility model is not done particular determination for the shape of the first groove.

Above-mentioned generating mechanism as shown in Figure 3 and Figure 4, is comprised of source of the gas, some valves, second groove 31, the 3rd cylinder 32, Z-type connector 33, a position control 34 and a baffle plate 35.Wherein valve is connected with source of the gas and is opened on above-mentioned the second groove 31.Valve comprises again bottom valve 361 and sidewall valve 362, and described bottom valve 361 is opened in the bottom of above-mentioned the second groove 31, and source of the gas can vertically upward spray gas after opening; And sidewall valve 362 is opened on the both sides cell wall of above-mentioned the second groove 31, the axle center of this sidewall valve 362 and the second groove 31 form the angle of 10～80 °, guarantee that air-flow can blow to spheroid to be measured.Above-mentioned bottom valve 361 and and sidewall valve 362 coordinate spheroid to be measured can original position be rotatablely moved before above-mentioned baffle plate 35, realize the generate of sphere.Described position control 34 is fixed on floor, the output of position control 34 is connected with above-mentioned the 3rd cylinder 32, the 3rd cylinder 32 is connected with baffle plate 35 by above-mentioned Z-type connector 33 and drives baffle plate 35 to move up and down, and then controls the spheroid of different size and the position relationship between valve.35 of described V-baffles are perpendicular in described the second groove 31.The first groove 21 in the second groove 31You rhythm control mechanism 2 in generating mechanism extends.Above-mentioned the second groove is preferably V-type groove, because spheroid to be measured need original position rotatablely move in this second groove, the contact-making surface between V-type groove and spheroid to be measured is minimum, and resistance is minimum, the original position rotation of the most difficult obstruction spheroid to be measured.Same, above-mentioned baffle plate is preferably the baffle plate that coordinates the second groove shapes, so baffle plate is preferably V-baffle.

As shown in Figure 5 and Figure 6, described visual mechanisms 4 comprises some light sources and a taper cover 41.This taper cover 41 is positioned at the top of above-mentioned generating mechanism 3, and the generate of spheroid to be measured is all in the interior realization of this taper cover 41, and light source is installed on taper cover 41 inside.On taper cover 41, according to the position of visual effect, offer a plurality of detections hole, make vision system the surface of spheroid to be measured can be detected.Above-mentioned vision system also comprises camera 43, camera lens, for portal frame 42 and the DPA data processing activity of fixed camera 43.The quantity of above-mentioned camera 43 is consistent with the quantity in above-mentioned detection hole.The quantity of the preferred camera of the utility model embodiment is 3, comprise first camera 431, second camera 432 and third phase machine 433, and the angle between first camera 431 and second camera 432, second camera 432 and the 3rd smooth camera 433 is all preferably 60 °, realize the shooting of spherical crown part surface as shown in Figure 4.

As shown in Figure 7 and Figure 8, above-mentioned sorting system 5 comprises oscillating cylinder 51, pendulum 54, sub-material guide rail 52 and magazine 53.Wherein pendulum 54 is positioned at the porch of sub-material guide rail 52, and oscillating cylinder 51 is fixed on floor, and the output of oscillating cylinder 51 is connected with pendulum 54 through the bottom surface of above-mentioned sub-material guide rail 52.Above-mentioned magazine 53 is positioned at the exit of sub-material guide rail 52, and magazine 53 quantity are consistent with the export volume of sub-material guide rail 52.The utility model embodiment is inverted Y-shaped sub-material guide rail preferably, the porch of this sub-material guide rail 52 is stopped by pendulum 54, the rear sub-material guide rail of pendulum 54 divides 52 to be two rails, article one, be the lead out track of qualified spheroid, another is the lead out track of defective spheroid, and spheroid enters corresponding track and finally enters corresponding magazine according to testing result.

As shown in Figure 9, the utility model, when detecting spherome surface quality, is divided into following step:

S1, functional parameter is set

Comprise gear pin position, gas pressure, catch position, vision parameter etc. are set;

S2, startup automatic charging machine

Spheroid to be measured is sent to rhythm control mechanism by automatic charging machine;

S3, rhythm control mechanism controls spheroid to be measured enter generating mechanism one by one

The second cylinder moving, the second gear pin rises, and after spheroid to be measured is stopped by the second gear pin, the first cylinder moving rises the first gear pin, and the second gear pin declines and discharges spheroid to be measured, and spheroid to be measured relies on self gravitation to enter generating mechanism;

S4, generating mechanism are by spherome surface generate to be measured

The 3rd cylinder moving, baffle plate declines and stops that spheroid to be measured moves on, and is located at the detection position in generating mechanism.Source of the gas is opened, and bottom valve and sidewall valve are blown, and spheroid to be measured rotates in position;

S5, vision system gather image and process

Camera is taken spherome surface to be measured, because spheroid to be measured is done original position and is rotatablely moved, therefore camera can collect the image of spheroid integral surface to be measured, DPA data processing activity in vision system is analyzed the image collecting, and judges whether spherome surface quality to be measured reaches technological requirement;

After S6, IMAQ complete, spheroid to be measured moves forward

After collection completes, the 3rd cylinder moving, baffle plate is upwards regained, and spheroid to be measured moves forward under the effect of the air-flow of sidewall valve;

S7, pendulum sub-material

After spherome surface analysis of image data to be measured is completed, according to judged result, determine whether to need to start oscillating cylinder.When spherome surface quality to be measured meets technological requirement, oscillating cylinder is motionless, and pendulum blocks the sub-material guide rail entrance of defective work; When spherome surface quality to be measured does not meet technological requirement, oscillating cylinder starts, and pendulum blocks the sub-material guide rail entrance of certified products.

The utility model discloses a kind of sensor sealing protective box, compared with prior art, the utlity model has following advantage:

(1) feeding beat can be controlled, and reduces the interference between spheroid to be measured, while guaranteeing each detection, only has a spheroid to be measured to pass through;

(2) supply gas and make spheroid to be measured do original position to rotatablely move, guarantee that spheroid generate is comprehensively complete, improve the accuracy detecting;

(3) size of difference spheroid to be measured is had to stronger adaptability;

(4) whole testing process can not produce loss to spheroid to be measured;

(5) testing process is full-automatic, reduces the requirement to operating personnel, improves accuracy of detection and the degree of accuracy.

To those skilled in the art, obviously the utility model is not limited to the details of above-mentioned one exemplary embodiment, and in the situation that not deviating from spirit of the present utility model or essential characteristic, can realize the utility model with other concrete form.Therefore, no matter from which point, all should regard embodiment as exemplary, and be nonrestrictive, scope of the present utility model is limited by claims rather than above-mentioned explanation, is therefore intended to include in the utility model dropping on the implication that is equal to important document of claim and all changes in scope.Any Reference numeral in claim should be considered as limiting related claim.

In addition, be to be understood that, although this description is described according to embodiment, but not each embodiment only comprises an independently technical scheme, this narrating mode of description is only for clarity sake, those skilled in the art should make description as a whole, and the technical scheme in each embodiment also can, through appropriately combined, form other embodiments that it will be appreciated by those skilled in the art that.

Claims (10)

1. a spherome surface quality detection device, it is characterized in that: described spherome surface quality detection device comprises automatic charging machine, rhythm control mechanism, generating mechanism, vision system, sorting system, before described rhythm control mechanism is positioned at the end and generating mechanism of automatic charging machine, control spheroid to be measured and enter one by one described generating mechanism, described rhythm control mechanism comprises two groups of blocking mechanisms, described two groups of blocking mechanisms in turn movable control spheroid to be measured advancing and mobile.

2. spherome surface quality detection device according to claim 1, it is characterized in that: described rhythm control mechanism is comprised of the first blocking mechanism and the second blocking mechanism and first groove, described the first blocking mechanism comprises the first cylinder, the first connector, the first spiral inching device and the first gear pin, described the second blocking mechanism comprises the second cylinder, the second connector, the second spiral inching device and the second gear pin, wherein said first, the second cylinder is fixed on floor, described first, the second spiral inching device is connected to described first, the upper end of the second cylinder, described first, the second spiral inching device and described first, the second gear pin is respectively by described first, the second connector connects.

3. spherome surface quality detection device according to claim 2, is characterized in that: the distance between described the first gear pin and the second gear pin is sphere diameter to be measured 1～1.5 times.

4. spherome surface quality detection device according to claim 1, it is characterized in that: the output guide rail of described automatic charging machine is V-type, and this output guide rail has the inclination of 1 °～5 °.

5. spherome surface quality detection device according to claim 1, it is characterized in that: described generating mechanism is by source of the gas, some valves, second groove, the 3rd cylinder, a Z-type connector, a position control and a baffle plate form, wherein said valve is connected with described source of the gas and is opened on described the second groove, described position control is fixed on floor, the output of position control is connected with described the 3rd cylinder, described the 3rd cylinder is connected with described baffle plate by described Z-type connector and drives baffle plate to move up and down, described baffle plate position is perpendicular in described the second groove.

6. spherome surface quality detection device according to claim 5, it is characterized in that: described valve comprises bottom valve and sidewall valve, described bottom valve is opened in the bottom of described the second groove, described sidewall valve is opened on the both sides cell wall of the second groove, and the axle center of described sidewall valve and described the second groove form the angle of 10～80 °.

7. spherome surface quality detection device according to claim 1, it is characterized in that: described vision system comprises some light sources and a taper cover, described taper cover is positioned at the top of described generating mechanism, described light source is arranged on the inside of described taper cover, on described taper cover, according to the position of visual effect, offers a plurality of detections hole.

8. spherome surface quality detection device according to claim 7, it is characterized in that: described vision system further comprises camera, camera lens, for portal frame and the DPA data processing activity of fixed camera, described camera angle capable of regulating, described camera quantity is consistent with the quantity in described detection hole.

9. spherome surface quality detection device according to claim 8, it is characterized in that: described camera quantity is 3, comprise: first camera, second camera and third phase machine, the angle between described first camera and second camera, second camera and third phase machine is 60 °.

10. spherome surface quality detection device according to claim 1, it is characterized in that: described sorting system comprises oscillating cylinder, pendulum, sub-material guide rail and magazine, described pendulum is positioned at the porch of sub-material guide rail, described oscillating cylinder is fixed on floor, the output of oscillating cylinder is connected with described pendulum through described sub-material guide rail, described magazine is positioned at the exit of described sub-material guide rail, and magazine quantity is consistent with the export volume of sub-material guide rail.