阅读说明：本技术 一种全聚焦技术在管道焊缝中的应用 (Application of full-focusing technology in pipeline welding seam ) 是由 马丹 李健 李宝超 姚国征 张志红 刘春杰 陈宝龙 于 2021-08-27 设计创作，主要内容包括：本发明涉及全聚焦技术领域,具体为一种全聚焦技术在管道焊缝中的应用,包括有计算机,所述计算机的输出端设置有三个连接口,三个连接口分别连接有TFM组件、FSTFM组件与储存器,所述TFM组件的一端端口连接有管道试件,所述管道试件的一侧连接有第二信号传感器,所述FSTFM组件一侧连接着显示组件,所述显示组件的端连接有第一信号传感器,所述第一信号传感器的一端连接有控制芯片；有益效果：通过计算机的作用,将切割焊缝的位置进行编辑,编辑呈信号后,将信号发送至TFM组件与FSTFM组件,TFM组件收到信号后发送至管道试件工位,这时管道试件工位则会配合收到的信号进行位置变换,以便切割器进行切割,随后管道试件工位将信号发送至第一信号传感器。(The invention relates to the technical field of full focusing, in particular to application of a full focusing technology in a pipeline welding seam, which comprises a computer, wherein the output end of the computer is provided with three connecting ports, the three connecting ports are respectively connected with a TFM component, an FSTFM component and a storage device, one end port of the TFM component is connected with a pipeline test piece, one side of the pipeline test piece is connected with a second signal sensor, one side of the FSTFM component is connected with a display component, one end of the display component is connected with a first signal sensor, and one end of the first signal sensor is connected with a control chip; has the advantages that: through the effect of computer, will cut the position of welding seam and edit, after the edition is the signal, with signal transmission to TFM subassembly and FSTFM subassembly, the TFM subassembly receives the signal and sends to pipeline test piece station, at this moment pipeline test piece station then can cooperate the signal that receives to carry out the position transform to the cutterbar cuts, pipeline test piece station is with signal transmission to first signal sensor afterwards.)

1. The application of the full-focusing technology in the pipeline welding seam comprises a computer (1), and is characterized in that: the output end of the computer (1) is provided with three connecting ports, the three connecting ports are respectively connected with a TFM component (2), an FSTFM component (3) and a storage device (9), one end port of the TFM component (2) is connected with a pipeline test piece (5), one side of the pipeline test piece (5) is connected with a second signal sensor (10), one side of the FSTFM component (3) is connected with a display component (6), one end of the display component (6) is connected with a first signal sensor (4), one end of the first signal sensor (4) is connected with a control chip (8), the output end of the control chip (8) is connected with an ultrasonic probe (7), the ultrasonic probe (7) is in signal connection with the second signal sensor (10), one side of the second signal sensor (10) is connected with a cutter (12), and the second signal sensor (10) is in signal connection with the cutter (12), and a welding gun (11) is arranged on one side of the cutter (12).

2. Use of a full focus technique in a pipe weld according to claim 1, wherein: the ultrasonic probe (7) is in signal communication with the second signal sensor (10).

3. Use of a full focus technique in a pipe weld according to claim 1, wherein: the TFM component (2) is in signal communication with the FSTFM component (3).

4. Use of a full focus technique in a pipe weld according to claim 1, wherein: the ultrasonic probe (7) is specifically an Olympus phased array probe.

5. Use of a full focus technique in a pipe weld according to claim 1, wherein: the storage (9) is in signal connection with the TFM assembly (2), the FSTFM assembly (3), the ultrasonic probe (7) and the first signal sensor (4).

6. Use of a full focus technique in a pipe weld according to claim 1, wherein: the use frequency of the ultrasonic probe (7) is 5 MHz-10 MHz.

7. Use of a full focus technique in a pipe weld according to claim 1, wherein: the display component (6) is in signal communication with the TFM component (2).

Technical Field

The invention relates to the technical field of full focusing, in particular to application of a full focusing technology in pipeline welding seams.

Background

A full-focus imaging algorithm in the phased array ultrasonic detection technology is a virtual focus post-processing imaging technology based on full matrix data, and has the advantages of high precision, flexible algorithm and the like, so that the full-focus imaging algorithm becomes a research hotspot in recent years.

And the full focusing technology for the pipeline welding seam can accurately position the position of the required welding seam, and the welding is carried out by a welding gun, so that the high efficiency is ensured.

Disclosure of Invention

The invention aims to provide an application of a full focusing technology in a pipeline welding seam so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the application of the full-focusing technology in the pipeline welding seam comprises a computer, wherein three connectors are arranged at the output end of the computer, the three connectors are respectively connected with a TFM assembly, an FSTFM assembly and a storage, a pipeline test piece is connected to one end port of the TFM assembly, a second signal sensor is connected to one side of the pipeline test piece, a display assembly is connected to one side of the FSTFM assembly, a first signal sensor is connected to one end of the display assembly, a control chip is connected to one end of the first signal sensor, an ultrasonic probe is connected to the output end of the control chip and is in signal connection with the second signal sensor, a cutter is connected to one side of the second signal sensor, the second signal sensor is in signal connection with the cutter, and a welding gun is arranged on one side of the cutter.

Through the technical scheme, when the pipeline welding seam signals are sent to the TFM component and the TFM component, the TFM component receives signals and sends the signals to the pipeline test piece station.

Preferably, the ultrasound probe is in signal communication with the second signal transducer.

Through above-mentioned technical scheme, through ultrasonic probe's effect, the particular case in the inside gap of observable pipeline sends the condition to the cutterbar through second signal sensor's effect again and cuts the welding seam.

Preferably, the TFM component is in signal communication with the FSTFM component.

Through the technical scheme, the whole imaging algorithm is more comprehensive through signal interaction between the TFM component and the FSTFM component.

Preferably, the ultrasound probe is an Olympus phased array probe.

Preferably, the storage is in signal connection with the TFM assembly, the FSTFM assembly, the ultrasonic probe and the first signal sensor.

Through above-mentioned technical scheme, through the effect of accumulator, can carry out the record with whole experimental process and store, be convenient for use next time.

Preferably, the use frequency of the ultrasonic probe is 5 MHz-10 MHz.

Preferably, the display component is in signal communication with the TFM component.

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

1. this application of full focus technique in pipeline welding seam, through the effect of computer, the position of cutting the welding seam is edited, after the edition is the signal, with signal transmission to TFM subassembly and FSTFM subassembly, the TFM subassembly receives the signal after-sending to pipeline test piece station, at this moment pipeline test piece station then can cooperate the signal of receiving to carry out the position transform, so that the cutterbar cuts, pipeline test piece station sends the signal to first signal sensor afterwards, by first signal sensor's effect, with signal transmission to the cutterbar, cut through the cutterbar, afterwards by welder's effect again, carry out the welding seam to holistic pipeline.

2. The application of the full-focusing technology in the pipeline welding seam can detect the specific condition of the internal gap of the pipeline through the action of the ultrasonic probe, and then sends the condition to the cutter for cutting the welding seam through the action of the second signal sensor.

3. The application of the full-focusing technology in the pipeline welding seam enables the whole imaging algorithm to be more comprehensive through signal interaction between the TFM component and the FSTFM component.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

In the figure: 1. a computer; 2. a TFM component; 3. a FSTFM component; 4. a first signal sensor; 5. a pipeline test piece; 6. a display component; 7. an ultrasonic probe; 8. a control chip; 9. A reservoir; 10. a second signal sensor; 11. a welding gun; 12. and a cutter.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a technical solution provided by the present invention is:

an application of a full-focusing technology in a pipeline welding seam comprises a computer 1, wherein the output end of the computer 1 is provided with three connecting ports, the three connecting ports are respectively connected with a TFM component 2, an FSTFM component 3 and a storage 9, one end port of the TFM component 2 is connected with a pipeline test piece 5, one side of the pipeline test piece 5 is connected with a second signal sensor 10, one side of the FSTFM component 3 is connected with a display component 6, one end of the display component 6 is connected with a first signal sensor 4, one end of the first signal sensor 4 is connected with a control chip 8, the output end of the control chip 8 is connected with an ultrasonic probe 7, the ultrasonic probe 7 is in signal connection with the second signal sensor 10, one side of the second signal sensor 10 is connected with a cutter 12, and the second signal sensor 10 is in signal connection with the cutter 12, a welding gun 11 is provided at one side of the cutter 12.

Through the technical scheme, when the pipeline welding device is used, the position of a welding seam to be cut is edited through the action of the computer 1, after the editing is a signal, the signal is sent to the TFM component 2 and the FSTFM component 3, the TFM component 2 receives the signal and then sends the signal to the pipeline test piece 5 station, at the moment, the pipeline test piece 5 station can be matched with the received signal to perform position conversion, so that the cutter 12 performs cutting, then the pipeline test piece 5 station sends the signal to the first signal sensor 4, the signal is sent to the cutter 12 through the action of the first signal sensor 4, the cutting is performed through the cutter 12, and then the welding seam is performed on the whole pipeline through the action of the welding gun 11.

Preferably, the ultrasound probe 7 is in signal communication with the second signal transducer 10.

Through above-mentioned technical scheme, through the effect of ultrasonic probe 7, the concrete condition of the inside gap of detectable pipeline is with the condition again through the effect of second signal sensor 10 send the cutter 12 to carry out the cutting welding seam.

Preferably, the TFM module 2 is in signal communication with the FSTFM module 3.

Through the technical scheme, the whole imaging algorithm is more comprehensive through signal interaction between the TFM component 2 and the FSTFM component 3.

Preferably, the ultrasound probe 7 is embodied as an Olympus phased array probe.

Preferably, the memory 9 is in signal connection with the TFM module 2, the FSTFM module 3, the ultrasound probe 7 and the first signal sensor 4.

Through above-mentioned technical scheme, through the effect of accumulator 9, can carry out the record with whole experimental process and store, be convenient for use next time.

Preferably, the frequency of the ultrasonic probe 7 is 5MHz to 10 MHz.

Preferably, the display module 6 is in signal communication with the TFM module 2.

When the full-focusing technology of the embodiment is applied to a pipeline welding seam, the position of the cutting welding seam is edited through the action of the computer 1, the edited signal is sent to the TFM component 2 and the FSTFM component 3, the TFM component 2 receives the signal and then sends the signal to the pipeline test piece 5 station, at the moment, the pipeline test piece 5 station can perform position transformation by matching the received signal so as to be convenient for a cutter 12 to cut, then the pipeline test piece 5 station sends the signal to the first signal sensor 4, the signal is sent to the cutter 12 through the action of the first signal sensor 4, the cutting is performed through the cutter 12, then the welding seam is performed on the whole pipeline through the action of the welding gun 11, the specific situation of the internal gap of the pipeline can be detected through the action of the ultrasonic probe 7, and then the situation is sent to the cutter 12 through the action of the second signal sensor 10 to cut the welding seam, through the signal interaction between TFM subassembly 2 and FSTFM subassembly 3 to make whole imaging algorithm more comprehensive, through the effect of memory 9, can record the storage with whole experimental process, be convenient for use next time.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.