CN204925003U - Vortex line sweep thermal imaging detecting system - Google Patents

Abstract

The utility model discloses a vortex line sweep thermal imaging detecting system, including the trigger that has two at least outputs, an output of trigger links to each other with the coil through the eddy current heating module, other outputs of trigger link to each other with at least one thermal imaging collection system respectively, every thermal imaging collection system all disposes the camera lens that is used for adjusting the visual field size, every thermal imaging collection system's output links to each other with the computer respectively, still includes the scanning control module that links to each other with the output of computer, the output of scanning control module links to each other with the telecontrol equipment, clamping device has on the telecontrol equipment, clamping device links firmly with every thermal imaging collection system with the coil respectively, perhaps clamping device is examined the object with the quilt and is linked firmly. Compared with the prior art, the utility model discloses convenient to use, detection efficiency is high, imaging is good, defect detecting's precision is high, detects with low costs, testing result reliability height.

Description

A kind of vorticity line scanning calorimeter image-forming detecting system

Technical field

The utility model belongs to the fields such as equipment Non-Destructive Testing, monitoring structural health conditions and production quality control, particularly a kind of vorticity line scanning calorimeter image-forming detecting system.

Background technology

Along with the development of modern science and industrial technology, Dynamic Non-Destruction Measurement has become the necessary means ensureing product quality and equipment security of operation.The detection of large-scale component and quality control are just becoming a difficult point of field of non destructive testing, and in order to ensure the reliability detected, General Requirements detection system can be run continuously, imaging display, and reduces costs as far as possible.

Dynamic Non-Destruction Measurement representative at present mainly contains the technology such as ray detection, Ultrasonic Detection, Liquid penetrant testing, Magnetic testing, EDDY CURRENT and thermal imaging detection.

Thermal imaging detection technique adopts thermal source to heat checked object, adopts the temperature information on thermal imaging system observation and record checked object surface, to detect checked object surface and inner defect (crackle, layering etc.) and to assess.Thermal imaging detection technique has noncontact, non-demolition, without the need to coupling, the advantage such as area of detection is large, speed is fast, has been widely used in the fields such as Aeronautics and Astronautics, oil, chemical industry, electric power, nuclear energy.

Eddy heating for heating, is also called induction heating, is the Novel heating technology of a kind of efficient, energy-conservation, material-saving, environmental protection and safety.Conductive material is placed in high-frequency alternating elect magnetic field, according to Faraday's electromagnetic induction law, in conductive material, will eddy current be produced.According to Joule law, partial vortices will be converted into heat energy, then electric conduction of heating material.

The thermal imaging detection technique of eddy heating for heating mode is adopted to be called eddy current thermal imaging detection technique.Eddy current thermal imaging detection technique have noncontact, non-demolition, without the need to coupling, the advantage such as area of detection is large, speed is fast, conductive-type material can be detected, as carbon fibre composite, metal-base composites, metal and alloy thereof, also the workpiece containing conductive material can be detected, as coating coat system on the metallic substrate.

In existing eddy current thermal imaging detection system, the position of thermal source and thermal imaging system all immobilizes, and by applying high-frequency ac current to spiral winding, utilizing spiral winding to heat checked object, utilizing thermal imaging system to carry out imaging.

Therefore, there is following shortcoming in existing eddy current thermal imaging detection system:

The first, because the position of thermal source and thermal imaging system immobilizes, admittedly can only Static Detection be implemented, can not detection of dynamic be implemented, need when detecting large-scale component the position repeatedly configuring thermal source and thermal imaging system, thus reduce detection efficiency;

The second, due to the restriction of conventional this body structure of spiral winding, cause the heating of checked object uneven, thus cause that imaging effect is poor, the precision of defects detection is low;

3rd, because the position of thermal source and thermal imaging system all immobilizes, two-dimentional thermal imaging system must be adopted could to carry out temperature acquisition in a big way, and the cost of two dimensional imager is high.

Summary of the invention

Existing eddy current thermal imaging detection system detection efficiency is low, imaging effect is poor, detection precision is low, cost is high.The purpose of this utility model is, for the above-mentioned deficiency of prior art, provides a kind of vorticity line scanning calorimeter image-forming detecting system.

For solving the problems of the technologies described above, the technical scheme that the utility model adopts is:

A kind of vorticity line scanning calorimeter image-forming detecting system, comprise the trigger with at least two output terminals, an output terminal of described trigger is connected with coil by eddy heating for heating module, other output terminal of described trigger is connected with at least one thermal imaging harvester respectively, described each thermal imaging harvester all configures the camera lens regulating visual field size, the output terminal of described each thermal imaging harvester is connected with computing machine respectively, also comprise the scan control module be connected with the output terminal of computing machine, the output terminal of described scan control module is connected with telecontrol equipment, described telecontrol equipment has clamping device, described clamping device is connected with coil and each thermal imaging harvester respectively, or described clamping device and checked object are connected.

Utilize computer drives scan control module work, scan control module drive telecontrol equipment moves, and telecontrol equipment is moved by clamping device band moving winding and thermal imaging harvester, or telecontrol equipment is moved by clamping device checked object.Thus the detection of dynamic achieved checked object, when checked object is larger, the position without the need to reconfiguring detection system can realize the comprehensive inspection to checked object, and easy to use, detection efficiency is high.

According to checked object performance and detect the difference of demand, thermal imaging harvester can be regulated to the distance of coil, and distance is larger, and the time that heat transmits is longer, thus it is larger to detect the degree of depth, but while also corresponding growth detection time.

Simultaneously can also according to the sweep velocity of actual test condition and requirements set scan control module and sweep time, the power of setting eddy heating for heating module, electric current and frequency, the sample frequency etc. of setting thermal imaging harvester.

As a kind of optimal way, described coil is linearity coil, that described linearity coil implements linear heat to checked object and the moving direction of telecontrol equipment is perpendicular.

Utilize linearity coil to checked object homogeneous heating, imaging effect is good, the precision of defects detection is high.

As a kind of optimal way, described each thermal imaging harvester is one dimension thermal imaging system, or described each thermal imaging harvester is array infrared sensor and acquisition system.

Thermal imaging harvester is one dimension thermal imaging system, or array infrared sensor and acquisition system, gather multiple one-dimension temperature array and be transferred to computing machine, multiple one-dimension temperature array composing images that computing machine will collect, Detection results can be reached equally, instead of original two-dimentional thermal imaging system, reduce testing cost.Thermal imaging harvester also can choose two-dimentional thermal imaging system, is equivalent to multiple one dimension thermal imaging systems with different distance, can realizes the detection of checked object different depth simultaneously.

Further, when the number of thermal imaging harvester is greater than 1, each thermal imaging harvester is different respectively from the distance between coil.

Different from the distance between coil by arranging thermal imaging harvester, the imaging to checked object different depth can be realized, improve the reliability of testing result.

As a kind of optimal way, described coil and thermal imaging harvester lay respectively at homonymy or the both sides of checked object.This kind of structure improves the configurability of system.

When coil and thermal imaging harvester are positioned at the homonymy of checked object, what detection system was taked is reflection detection mode; When coil and thermal imaging harvester lay respectively at the both sides of checked object, what detection system was taked is penetration-detection mode, when checked object size is less, when heat can be passed to the opposite side of coil fast, can take penetration-detection mode.

Compared with prior art, the utility model is easy to use, and detection efficiency is high, and imaging effect is good, and the precision of defects detection is high, and testing cost is low, and testing result reliability is high.

Accompanying drawing explanation

Fig. 1 is the structural representation of the utility model detection system one embodiment.

Fig. 2 is the structural representation of another embodiment of the utility model detection system.

Fig. 3 is the new images schematic diagram be made up of m one-dimension temperature array.

Wherein, 1 is computing machine, and 2 is eddy heating for heating module, and 3 is linearity coil, and 4 is scan control module, and 5 is telecontrol equipment, and 6 is trigger, and 7 is one dimension thermal imaging system, and 8 is camera lens, and 9 is checked object, and 10 is clamping device, and 11 is one-dimension temperature array.

Embodiment

As shown in Figure 1, one embodiment of the utility model detection system comprises the trigger 6 with two output terminals, an output terminal of described trigger 6 is connected with linearity coil 3 by eddy heating for heating module 2, another output terminal of described trigger 6 is connected with one dimension thermal imaging system 7, described one dimension thermal imaging system 7 configures the camera lens 8 regulating visual field size, the output terminal of described one dimension thermal imaging system 7 is connected with computing machine 1, also comprise the scan control module 4 be connected with the output terminal of computing machine 1, the output terminal of described scan control module 4 is connected with telecontrol equipment 5, described telecontrol equipment 5 has clamping device 10, described clamping device 10 is connected with linearity coil 3 and one dimension thermal imaging system 7 respectively, the moving direction that described linearity coil 3 pairs of checked objects 9 implement one side of linear heat and telecontrol equipment 5 is perpendicular.Described linearity coil 3 and one dimension thermal imaging system 7 are positioned at the homonymy of checked object 9, namely reflect detecting pattern.

As shown in Figure 2, another embodiment of the utility model detection system comprises the trigger 6 with two output terminals, an output terminal of described trigger 6 is connected with linearity coil 3 by eddy heating for heating module 2, another output terminal of described trigger 6 is connected with one dimension thermal imaging system 7, described one dimension thermal imaging system 7 configures the camera lens 8 regulating visual field size, the output terminal of described one dimension thermal imaging system 7 is connected with computing machine 1, also comprise the scan control module 4 be connected with the output terminal of computing machine 1, the output terminal of described scan control module 4 is connected with telecontrol equipment 5, described telecontrol equipment 5 has clamping device 10, described clamping device 10 is connected with checked object 9, the moving direction that described linearity coil 3 pairs of checked objects 9 implement one side of linear heat and telecontrol equipment 5 is perpendicular.Described linearity coil 3 and one dimension thermal imaging system 7 are positioned at the homonymy of checked object 9, namely reflect detecting pattern.

Fig. 3 shows the new images schematic diagram be made up of m one-dimension temperature array 11, and the size of each one-dimension temperature array 11 is the new images that 1 × n, m one-dimension temperature array 11 constitutes containing m × n pixel.

The course of work of the utility model detection system is as follows:

1) use clamping device 10 that linearity coil 3 and one dimension thermal imaging system 7 are fixed on telecontrol equipment 5, or use clamping device 10 that checked object 9 is fixed on telecontrol equipment 5;

2) adjust the position of linearity coil 3, make linearity coil 3 be positioned at the side in the tested region of checked object 9;

3) adjust position and the camera lens 8 of one dimension thermal imaging system 7, make the one dimension visual field of one dimension thermal imaging system 7 at the rear of linearity coil 3, according to the distance of testing conditions with the demand of detection determination one dimension thermal imaging system 7 to linearity coil 3;

4) running parameter such as sweep velocity v, sweep time of scan control module 4 is set;

5) parameter such as power, electric current, frequency of eddy heating for heating module 2 is set;

6) parameters such as the sample frequency f of one dimension thermal imaging system 7 are set;

7) trigger 6 controlled vortex flow heating module 2 and one dimension thermal imaging system 7 run;

8) eddy heating for heating module 2 is applied to linearity coil 3 electric current;

9) linearity coil 3 produces alternating electromagnetic field, in checked object 9, produce eddy current, linear heat checked object 9;

10) one dimension thermal imaging system 7 gathers the temperature on checked object 9 surface, and as one-dimension temperature array 11, size is 1 × n, and one-dimension temperature array 11 is transferred to computing machine 1;

11) computing machine 1 makes scan control module 4 work;

12) scan control module 4 actuation movement device 5 moves with speed v;

13) telecontrol equipment 5 leading linear coil 3 and one dimension thermal imaging system 7 move with speed v, as shown in Figure 1; Or telecontrol equipment 5 drives checked object 9 to move with speed v, through linearity coil 3 and one dimension thermal imaging system 7, as shown in Figure 2;

14) computing machine 1 is configured to new images multiple one-dimension temperature array 11;

15) by the spatial abnormal feature of temperature on new images, existing defects is judged whether;

16) by computing machine 1, eddy heating for heating module 2, scan control module 4 and one dimension thermal imaging system 7 are quit work.

Change the distance between one dimension thermal imaging system 7 and linearity coil 3, repeat above step, can realize the detection of different depth, the larger detection degree of depth of distance is larger.

Claims (5)

1. a vorticity line scanning calorimeter image-forming detecting system, comprise the trigger (6) with at least two output terminals, an output terminal of described trigger (6) is connected with coil by eddy heating for heating module (2), other output terminal of described trigger (6) is connected with at least one thermal imaging harvester respectively, described each thermal imaging harvester all configures the camera lens (8) regulating visual field size, the output terminal of described each thermal imaging harvester is connected with computing machine (1) respectively, it is characterized in that, also comprise the scan control module (4) be connected with the output terminal of computing machine (1), the output terminal of described scan control module (4) is connected with telecontrol equipment (5), described telecontrol equipment (5) has clamping device (10), described clamping device (10) is connected with coil and each thermal imaging harvester respectively, or described clamping device (10) and checked object (9) are connected.

2. vorticity line scanning calorimeter image-forming detecting system as claimed in claim 1, it is characterized in that, described coil is linearity coil (3), and described linearity coil (3) implements the perpendicular with the moving direction of telecontrol equipment (5) of linear heat to checked object (9).

3. vorticity line scanning calorimeter image-forming detecting system as claimed in claim 1 or 2, it is characterized in that, described each thermal imaging harvester is one dimension thermal imaging system (7), or described each thermal imaging harvester is array infrared sensor and acquisition system.

4. vorticity line scanning calorimeter image-forming detecting system as claimed in claim 1, is characterized in that, when the number of thermal imaging harvester is greater than 1, each thermal imaging harvester is different respectively from the distance between coil.

5. vorticity line scanning calorimeter image-forming detecting system as claimed in claim 1, it is characterized in that, described coil and thermal imaging harvester lay respectively at homonymy or the both sides of checked object (9).