CN211772298U - Bud thread lace defect detection device based on machine vision - Google Patents

Abstract

The utility model belongs to the technical field of textile production, a bud silk lace defect detecting device based on machine vision is disclosed, including opening a book subassembly (1) and defect detecting component (2), its characterized in that: defect detection subassembly (2), including examining test table (24), examine test table (24) below and install an uncoiling subassembly (1), examine test table (24) back fixed mounting have rolling component (3), it is connected with the PLC controller electricity to open a book subassembly (1), and the PLC controller electricity is connected with rolling component (3). Not only richened fabrics trade defect detecting device, its detection precision is high moreover, and the real-time nature is strong.

Description

Bud thread lace defect detection device based on machine vision

Technical Field

The utility model belongs to the technical field of textile production, especially, relate to a bud silk lace defect detecting device based on machine vision.

Background

In the current textile industry, flaw detection or defect detection plays an important role in improving the quality of textiles, and a lace is no exception. At present, the detection of the lace in China mainly depends on manual detection. The traditional manual detection method is that the inspector makes an assessment according to personal experience. The method has the problems of low detection speed, high omission factor, non-uniform detection standard and the like, so that a novel, rapid and accurate automatic detection method for the fabric defects is urgently needed to be developed.

The existing textile defect detection device has the following schemes: (1) application number 201820594716.2, name a fabrics fault detection test platform, has the test bench, the support is installed to the left and right sides of test bench, and cloth off tracking mechanism is all installed to the both ends head of test bench and is used for making the cloth keep smooth compression roller, and the front end of test bench is installed and is opened a book the mount pad, and the rolling mount pad is installed to its rear end. The device does not have the capability of automatically detecting textile defects. (2) application number 201721303579.4, name a detect device of fabrics defect, including anti-skidding support callus on the sole, supporting legs connecting rod, workstation support frame, the dustproof safety cover of conveyer belt, control panel, testing result display screen, control button, fabrics detection device main part, conveyer belt anti-drop baffle, automatic handling manipulator, fabrics conveyer belt, the fabrics conveyer belt passes through mechanical connection in the middle of workstation support frame top. To above-mentioned scheme, adopt the conveyer belt to detect the fabrics defect, do not open a book subassembly and rolling part, thereby and different elastic material can arouse deformation to influence the testing result. (3) Application number 201820803164.1, title a textile defect detection device based on machine vision, including industry PC, FPGA controller, image acquisition device and textile transport mechanism, industry PC with FPGA controller both-way communication connects, image acquisition device with FPGA controller communication connects. For the third scheme, the resolution of the position and the angle of the light source is not clear, great influence is generated on the acquisition of the image, and the production cost is high and is not suitable for popularization in the market. The data is consulted to know that the main factor influencing the tension of the lace is the change of the linear velocity and the roll diameter. And a large number of simulation experiments show that the change of the linear velocity is the main reason influencing the change of the tension, and the constant of the linear velocity must be kept to keep the constant of the tension.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving this problem, to a series of drawbacks that above-mentioned bud silk lace detected at the flaw, provide a bud silk lace defect detecting device based on machine vision, not only richened fabrics trade defect detecting device, it detects the precision height moreover, and the real-time nature is strong. The probability of false detection or missed detection caused by the conventional manual detection of bud thread lace defects is reduced, and meanwhile, the high-speed industrial camera is used for replacing human eyes, so that the labor cost is saved, and the manual labor intensity is reduced.

In order to realize the purpose of the utility model, the technical proposal of the utility model is that:

the utility model provides a bud silk lace defect detecting device based on machine vision, includes and opens a book subassembly 1 and defect detecting component 2, its characterized in that: the defect detection assembly 2 comprises a detection table 24, wherein an aluminum frame 21 with a set angle is arranged on the detection table 24, and a high-speed industrial camera 22 and an illumination light source 23 matched with the detection are arranged on the aluminum frame 21 to form a machine vision system; detect the below of platform and install and open a book subassembly 1, detect platform back fixed mounting and have rolling component 3, open a book subassembly 1 and PLC controller electricity is connected, and the PLC controller electricity is connected with rolling component 3.

Preferably, the unwinding assembly 1 comprises a spindle 11, an unwinding slender rod 12, an unwinding shaft 13, a tension control structure 14, an unwinding servo motor 15, an unwinding servo motor driver 16, a spindle servo motor 17, a spindle servo motor driver 18, and a support iron stand 19, the supporting iron frame 19 is provided with a main shaft 11, an uncoiling slender rod 12 and an uncoiling shaft 13, a spindle servo motor 17 and a spindle servo motor driver 18 are arranged between the spindle 11 and the tension control structure 14, a linear velocity encoder is installed in the spindle servo motor 17, the spindle 11 is connected with the spindle servo motor 17 through an uncoiling belt two phase, a tension control structure 14 is arranged at the upper end of the uncoiling slender rod 12 to control the tension of the lace, the uncoiling shaft 13 is connected with an uncoiling servo motor 15 through an uncoiling belt I, and the uncoiling servo motor 15 is fixed on an uncoiling servo motor driver 16.

Preferably, the tension control structure comprises a movable iron sheet 141, a spring 142, an iron rod 143, a gear 144, a rolling disc 145 and a movable iron rod 146, wherein the movable iron rod 146 connected to the uncoiling slender rod 12 rotates to drive the rolling disc 145 and the gear 144 to move, the gear 144 touches the iron rod 143 in the rotation process, the tail end of the iron rod 143 is connected to the front end of one spring 142, and the tail end of the spring 142 is hooked on the lower part of the movable iron sheet 141 fixed on the support iron frame.

Preferably, the winding assembly 3 is the same as the unwinding assembly and the defect detecting assembly and comprises a winding supporting iron frame 34, the winding supporting iron frame 34 is fixed with a winding shaft 31, a winding servo motor 32 and a winding servo motor driver 33, the winding servo motor 32 is fixed above the winding servo motor driver 33, the winding shaft 31 and the winding servo motor 32 are connected through a winding belt 35, and a tension sensor for detecting the tension of the lace fabric roll is installed at the corners of the winding supporting iron frame 34 and the detecting table.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses bud silk lace defect detection device test section adopts 120X 50(cm) to examine test table, can detect jumbo size bud silk lace defect, and its test section exists certain angle, has solved the meticulous problem that makes the decorative pattern unclear of preparation technology well. Open a book subassembly structure and increased linear velocity encoder and tension control structure for traditional fabrics defect detection, solved the bud silk lace because the linear velocity undersize causes the raw materials to roll up and piles up and lead to unable detection discernment or raw materials roll to be dragged or even destroy the problem of lace raw materials. The winding part structure increases the tension of the tension sensor for detecting the current lace cloth roll, and realizes the constancy of the tension through the PID controller. The device realizes the cooperative operation of the tension ring and the speed ring to ensure that the motion control is more accurate. Note: image processing: a method and a technique for removing noise, enhancing, restoring, segmenting, and extracting features of an image by a computer. Machine vision mainly uses a computer to simulate the visual function of a human, extracts information from an image of an objective object, processes and understands the information, and is applied to actual detection, measurement and control.

The utility model discloses when being applied to weaving factory production bud silk lace, detect its on the lace surface whether exist and lack footpath, broken latitude, defects such as leak. Plays an important role in improving the quality of the lace when detecting the lace in a textile factory. Can effectively aim at the characteristics of the lace, namely high elasticity, greatly shorten the development period of products and improve the competitiveness of the products in the market. The lace fabric constant-speed detection device can fill the vacancy that the lace defect detection does not occur in the market, according to the characteristic of high elasticity of the lace, the tension of the lace fabric is constant through the PID controller in the detection process, the linear speed of the lace raw material roll is detected in real time through the linear encoder, the speed is fed back to the PLC, the PLC compares the given rotating speed with the actually-measured rotating speed, and pulses are output to the servo drive to keep the constant of the linear speed of the lace raw material roll. The constant tension and velocity makes the entire device more stable. As described above, in the case where the object to be detected is a lace, a defect may be detected in a different type of textile by controlling the tension and the speed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a line speed control schematic diagram in an embodiment of the present invention.

Fig. 2 is a schematic diagram of tension control in an embodiment of the present invention.

Fig. 3 is the utility model discloses bud silk lace defect detecting device's schematic structure based on machine vision.

Figure 4 is the utility model discloses a bud silk lace defect detecting device opens a book the subassembly structure chart based on machine vision.

Fig. 5 is a tension control structure diagram of the bud thread lace defect detecting device based on machine vision.

Fig. 6 is an enlarged view of the tension control structure shown in fig. 5.

Figure 7 is the utility model discloses a bud silk lace defect detecting device's defect detecting component structure chart based on machine vision.

Figure 8 is the utility model discloses a bud silk lace defect detecting device's rolling part structure chart based on machine vision.

Fig. 9 is a flow chart of the device for detecting bud thread lace defect based on machine vision.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings.

As shown in fig. 1 and 2, a line speed schematic diagram and a tension control schematic diagram. Compared with the traditional textile detection, a linear speed encoder and a tension control structure are added to the uncoiling assembly, a tension sensor is added to the coiling part, the cooperative control of speed and tension is realized, and the characteristic that high elasticity is achieved in the textile based on lace is achieved.

The control principle of the linear velocity: v0(t) is a given rotating speed, V (t) is an actual rotating speed, E (t) is an error after the two are compared, the error is output to a servo drive, and the error is output to a servo motor through modifying pulses after the servo motor drive is calculated, so that the linear speed is corrected. The encoder is used as a rotating speed feedback device.

Tension control principle: t0(k) is a tension set value, T (k) is actual tension, an error E (k) is obtained after the two are compared, the error is output to a servo drive for calculation, after the servo drive is calculated, a pulse is output to a servo motor to control the rotating speed, the cloth winding speed V (k) is obtained by combining the winding diameter, and then the tension sensor detects the tension T (k) of the current lace cloth roll, so that the tension is constant through a PID controller.

As shown in fig. 3-8, a bud thread lace defect detecting device based on machine vision comprises an uncoiling assembly 1 and a defect detecting assembly 2, wherein the defect detecting assembly 2 comprises a detecting table 24, an aluminum frame 21 with a set angle is mounted on the detecting table 24, and a high-speed industrial camera 22 and an illumination light source 23 matched with the detecting are mounted on the aluminum frame 21 to form a machine vision system; detect the below of platform and install and open a book subassembly 1, detect platform back fixed mounting and have rolling component 3, open a book subassembly 1 and PLC controller electricity is connected, and the PLC controller electricity is connected with rolling component 3. The high-speed industrial camera is one or two cameras which are distributed at equal intervals, and the defect detection assembly can replace the two cameras with one camera by reducing the camera shooting area. The illumination light source is a common fluorescent lamp, and the detection table is a 120X 50cm detection table.

The uncoiling component 1 is electrically connected with a PLC (programmable logic controller), and the PLC is electrically connected with a coiling component 3. The uncoiling component 1 comprises a spindle 11, an uncoiling slender rod 12, an uncoiling shaft 13, a tension control structure 14, an uncoiling servo motor 15, an uncoiling servo motor driver 16, a spindle servo motor 17, a spindle servo motor driver 18 and a support iron frame 19, the supporting iron frame 19 is provided with a main shaft 11, an uncoiling slender rod 12 and an uncoiling shaft 13, a spindle servo motor 17 and a spindle servo motor driver 18 are arranged between the spindle 11 and the tension control structure 14, a linear velocity encoder is installed in the spindle servo motor 17, the spindle 11 is connected with the spindle servo motor 17 through an uncoiling belt two phase, a tension control structure 14 is arranged at the upper end of the uncoiling slender rod 12 to control the tension of the lace, the uncoiling shaft 13 is connected with an uncoiling servo motor 15 through an uncoiling belt I, and the uncoiling servo motor 15 is fixed on an uncoiling servo motor driver 16. When the uncoiling assembly starts to uncoil, the unbalanced pulling force of workers is ignored.

A worker loads a lace raw material roll into an uncoiling shaft 13, an uncoiling system obtains an error value between a given speed and an actual speed and outputs the error value to an uncoiling servo motor driver 16, the uncoiling servo motor driver 16 outputs the error value to an uncoiling servo motor 15 through modifying pulses after calculation, the uncoiling servo motor 15 drives the uncoiling shaft 13 through an uncoiling belt, the uncoiling shaft 13 starts to uncoil, then is drawn upwards through the unwinding slender rod 12, at the same time triggers the tension control structure 14, continues to be drawn upwards through the support iron frame 19 and winds around the main shaft 11, and the main shaft can obtain an error value between a given speed and an actual speed and outputs the error value to a main servo motor driver 18, the main servo motor driver 18 outputs the error value to a main shaft servo motor 17 through modifying pulses after calculation, the main shaft servo motor 17 drives the main shaft 11 through an uncoiling belt II, and the uncoiling assembly finishes entering a defect detection assembly. Open a book subassembly structure and increased linear velocity encoder and tension control structure for traditional fabrics defect detection, solved the bud silk lace because the linear velocity undersize leads to the raw materials to roll up and piles up and lead to unable detection discernment or the linear velocity undersize leads to the fact the raw materials to roll up and is dragged or even destroy the problem of lace raw materials. The design not only improves the accuracy of detecting the lace by the defect detecting assembly, but also enables the device to become more stable.

The tension control structure comprises a movable iron sheet 141, a spring 142, an iron rod 143, a gear 144, a rolling disc 145 and a movable iron rod 146, wherein the movable iron rod 146 connected to the uncoiling slender rod 12 rotates to drive the rolling disc 145 and the gear 144 to move, the gear 144 touches the iron rod 143 in the rotating process, the tail end of the iron rod 143 is connected to the front end of the spring 142, and the tail end of the spring 142 is hooked at the lower part of the movable iron sheet 141 fixed on a support iron frame.

Is distinguished from previous textile defect detection devices and is a further breakthrough in tension control in unwinding structures. When the lace raw material is stretched to the uncoiling slender rod 12 from the uncoiling shaft 13, the tension control structure 14 is triggered at the same time, the uncoiling slender rod 12 rotates ceaselessly, so that the movable iron rod 146 rotates, the movable iron rod drives the rolling disc 145 to move, the rolling disc 145 drives the gear 144 to move, the gear can touch the iron rod 143 in the rotating process, the tail end of the iron rod 143 is connected with the front end of the spring 142, and the tail end of the spring 142 is tightly hooked on the movable iron sheet 141. This structure has been opened a book the subassembly and has controlled certain tension, has alleviated the degree of difficulty of whole device motion control, and 3 end connection activity iron sheet 1 of iron rod are connected to 2 front ends of spring, and spring 2 plays the effect of a buffering.

As shown in FIG. 7, the lace material from the spindle 11 is extended onto the inspection table 24, an aluminum frame 21 parallel to the inspection table 24 is mounted at a distance of 80 cm from the beginning of the inspection table 24, two high-speed industrial cameras 22 are arranged on the aluminum frame 21 at equal distances, and the aluminum frame 21 is divided into three parts, on which an illumination light source 23 is mounted for detecting the lace defect on the inspection table 24. The two high-speed industrial cameras 22 can detect defects in the range of 80 × 60(cm) and the size of the object stage 4120 × 50(cm), and the light source is a common fluorescent lamp. The defect detection assembly is different from the traditional textile defect detection device in that a plane detection table is changed into an angle detection table, and the number of high-speed industrial cameras is increased from one to two. The oblique detection platform decomposes the gravity of raw materials perpendicular to the ground, the speed is more constant than that of a planar detection platform, and a large-size lace can be detected by adding one camera.

It is the same with uncoiling subassembly and defect detecting component of rolling subassembly 3, supports iron stand 34 including the rolling, rolling support iron stand 34 is fixed with rolling axle 31, rolling servo motor 32, rolling servo motor driver 33, rolling servo motor 32 is fixed in rolling servo motor driver 33 top, be connected with rolling belt 35 between rolling axle 31, the rolling servo motor 32, install the tension sensor who detects lace cloth and roll up tension at rolling support iron stand 34 and detection platform corner.

As shown in fig. 8, the device for detecting a lace defect, after detecting a lace defect, stretches from the detecting table 24 to the winding shaft 31, the winding assembly obtains an error value between a given speed and an actual speed, outputs the error value to the winding servo motor driver 33, outputs the calculated error value to the winding servo motor driver 33 through modifying pulses, outputs the calculated error value to the winding servo motor 32, and the winding servo motor 32 drives the winding shaft 31 through the winding belt 35, and these devices are all mounted on the winding support iron frame 34. The tension sensor is additionally arranged to detect the tension of the current lace cloth roll, and the tension is constant through the PID controller.

As shown in fig. 9, the method for using the device for detecting bud thread lace defect based on machine vision comprises the following steps,

the first step is as follows: the defect detection assembly is ready, a lace raw material roll is placed in the uncoiling shaft 13, after the operation is finished, the uncoiling assembly controls the uncoiling servo motor driver 16 to output a pulse signal to the uncoiling servo motor 15 through the PLC, and the uncoiling servo motor is conveyed by the uncoiling belt to the uncoiling shaft 13 to operate; when the defect detection detects that the raw material roll needs to be put in, the uncoiling servo motor is stopped, and the auxiliary relay M506 is set to be 1 and used for configuration reminding operators.

The second step is that: the bud thread lace material roll reaches the tension control structure 14 at a speed significantly different from the unwinding roll;

the third step: the uncoiling component controls a main shaft servo motor driver 18 to receive a pulse signal through a PLC controller and output the pulse signal to a main shaft servo motor 17, and the lace raw material coil passes through a main shaft 11 and then reaches a detection platform 24;

the fourth step: when the high-speed industrial camera and the lighting source work, the raw material roll with the lace is collected in real time; after the collection is finished, another lace with the same color is detected again and is matched with the lace template which is just collected, after a corresponding algorithm program is compiled in MATLAB software, whether a defect exists is judged, if yes, the step is skipped to the fifth step, otherwise, the device is automatically stopped;

the working principle of automatic shutdown is as follows: the PLC is driven to output an instruction, 1 is output to the TXT document, the configuration king reads the value of the TXT document in real time and gives the value to the auxiliary register M504, and when the TXT document is changed from 0 to 1, the register M504 is also changed from power-on to power-on, namely the auxiliary register is powered off.

The fifth step: before the bud thread lace raw material roll reaches the winding shaft 31, the winding system controls the winding servo motor driver 33 to output a pulse signal to the winding servo motor 32 through the PLC, and the winding is started;

and a sixth step: and finishing the operation after the rolling is finished.

1. Different from textile defect detection, the defect detection device of the lace realizes the cooperative operation of the tension ring and the speed ring to enable the motion control to be more accurate.

2. In the process of matching the two images, firstly, the images are preprocessed, then, the feature points of the two images are extracted, and finally, matching is carried out according to the feature points.

3. The device completes the data cooperation realization of motion control and bud thread lace image matching.

The embodiments described above are only a part of the embodiments of the present invention, and not all of them. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Claims (4)

1. The utility model provides a bud silk lace defect detecting device based on machine vision, includes opens a book subassembly (1) and defect detecting component (2), its characterized in that: the defect detection assembly (2) comprises a detection table (24), wherein an aluminum frame (21) with a set angle is mounted on the detection table (24), and a high-speed industrial camera (22) and a lighting source (23) matched with detection are mounted on the aluminum frame (21) to form a machine vision system; detect platform (24) below and install and open a book subassembly (1), detect platform (24) back fixed mounting and have rolling component (3), it is connected with the PLC controller electricity to open a book subassembly (1), and the PLC controller electricity is connected with rolling component (3).

2. The bud thread lace defect detection device based on the machine vision according to claim 1, wherein the uncoiling component (1) comprises a spindle (11), an uncoiling thin rod (12), an uncoiling shaft (13) and a supporting iron frame (19), the supporting iron frame (19) is provided with the spindle (11), the uncoiling thin rod (12) and the uncoiling shaft (13) from top to bottom, a spindle servo motor (17) and a spindle servo motor driver (18) are arranged between the spindle (11) and a tension control structure (14), a linear speed encoder is arranged in the spindle servo motor (17), the spindle (11) is connected with the spindle servo motor (17) through an uncoiling belt, the tension control structure (14) is arranged at one end of the uncoiling thin rod (12) to control the bud thread lace tension, the uncoiling shaft (13) is connected with the uncoiling servo motor (15) through an uncoiling belt I, the unwinding servomotor (15) is fixed to an unwinding servomotor driver (16).

3. The bud thread lace defect detection device based on the machine vision as claimed in claim 2, wherein the tension control structure comprises a gear (144), a rolling disc (145) and a movable iron rod (146), the movable iron rod (146) connected to the unwinding thin rod (12) rotates to drive the rolling disc (145) and the gear (144) to move, the gear (144) touches an iron rod (143) in the rotation process, the tail end of the iron rod (143) is connected to the front end of a spring (142), and the tail end of the spring (142) is hooked on the lower portion of a movable iron sheet (141) fixed on a support iron frame.

4. The lace defect detection device based on machine vision according to claim 1, wherein the winding component (3) comprises a winding supporting iron frame (34), the winding supporting iron frame (34) is fixed with a winding shaft (31), a winding servo motor (32) and a winding servo motor driver (33), the winding servo motor (32) is fixed above the winding servo motor driver (33), the winding shaft (31) and the winding servo motor (32) are connected through a winding belt (35), and a tension sensor for detecting tension of a lace fabric roll is installed at a corner of the winding supporting iron frame (34) and the detection table.

Images