Home (3)

Dasel sistemas - Ultrasound Technology

portada2DASEL is a company specialized in the development of high-end ultrasound technology. We offer at the same time flexible solutions according to each client requirements. Therefore the quality level in our products has not been neglected. Quality is a commitment that DASEL applies in all production areas to maintain traceability of manufactured products. For this reason the company has been certified ISO 9001:2015 by Bureau Veritas in the equipments production and calibration.

 

portada DASEL develops all its products with a modular architecture and using high-density re-configurable devices (FPGAs). Given the high cost for new hardware development, this design philosophy allows to adjust our systems to many different applications, with the incorporation of new functions or specific algorithms with no need to upgrade the equipment electronics.

ISO-9001 



Subscribe to newsletter

logo AAENDE   logo AEND   logo CDTI   logo CLUSTER AEROESPACIAL   logo HISPAROB  logo ICEX   logo pesi   logo PTFE

Last blog post

SITAU-TRITON in alliance

 

SITAU TRITON 

 

We present at 10th International Symposium on NDT in Aerospace 24-26 October 2018 in Dresde, Germany, the result of 2 years of work, with the achievement of a highly modular, scalable and affordable solution for high-speed ultrasound automated inspection, called SITAU TRITON.

 

 

 SITAU TRITON - Foto izquierda  SITAU TRITON - Foto centro  SITAU TRITON - Foto derecha

3 axes Cartesian System

Planar and Smooth curvature inspection

 XY or XZ scanning

High-spped Phased Array UT inspection

 Up to 896 Ultrasonics Channels

100% component inspection in one pass

Specialized for complex structures

Accurate robot trajectories

 Inmersion and Non contact inspection

 Optimized trajectory programming

and collision-free

Single-transducer, dual-frequency

Full compatible airscope

 

Detection of broken fiberglass in wind turbine blades

Sector                         : Eolic Energy

Material                     : Glass-Fiber Composite

Technology                : Phased Array

Equipment                 : SITAU-311-PRT

Keywords                  : Phased Array, GFRP, Aerogeneradores

 

Title                            : Detection of broken fiberglass in wind turbine blades

 

1. Introduction

 

Non destructive evaluation of windmill blades using ultrasound is a challenging task. Microstructure of fiberglass and resin composites (GFRP) introduces dispersive effects on ultrasound waves, which is seen as grain noise and produces high attenuation to ultrasonic signals. The traditional approach to overcome these problems is using low frequency transducers (typically 500 kHz), at the expense of loosing resolution, and hence, the capability to detect small defects or to inspect low thickness components.

In this work, results of the inspection of a thin GFRP layer (3mm) using phased-array technique are presented. The goal is to detect the presence of broken fibers in the material. A 5MHz array was used, along with a novel C-Scan processing technique, that allows to detect broken fibers with a resolution above 1 mm.

 

2. Materials and Methods

 

A phased array with 128 elements, inter-element pitch of 0.5mm and 5 MHz was used, in contact with the flat surface of the inspected part (see Figure 1). A SITAU-311-PRT equipment was used, with 32 channels multiplexed to 128 array elements, and linear B-Scans at 0º were performed.

Figure 1 – Inspection scheme

 

 

 

 

3. Results

 

The inspection goal is to detect broken fibers in a 3mm thickness layer of GFRP material. Shown images were obtained in field, from a real windmill blade, with a 500mm length cut in the inner glass-fiber layers.

Figure 2 (right) shows three of the B-Scans acquired along the fiber cut. As the ultrasonic pulse is not able to individually resolve each one of the glass fibers, what is seen in the images is an interference pattern between the echoes received by all fibers in the fabric. Relative position between fibers changes in the damaged zone, and so that, interference pattern also changes.

Presence of broken fibers does not necessary mean that received amplitude will decrease, because glass-fiber layers can become overlapped in the curing process. In that case, fiber damage cannot be detected by means of conventional amplitude C-Scan ( figure 2 left ).

DASEL has developed a novel processing algorithm (GFRP-Scan®), based on the interference pattern analysis, that is capable to detect broken fibers also at very low thickness layers ( figure 2 center ). As signal processing is based on global information contained at each B-Scan, it is little sensitive to configuration parameters, and hence, a very robust evaluation method.

 

 

Figure 2 – Images from a windmill blade with a 500mm length cut in the inner GFRP fibers. (Left) Conventional C-Scan (Center) GFRP-Scan®

(Rigth) Several B-Scans at different positions.

 

 

 

4. Conclusions

 

Beam focusing capability of phased array systems allows using higher frequencies when inspecting GFRP components and so that, a much higher resolution can be achieved compared to traditional low frequency transducers. In this work, the feasibility of detecting broken glass fibers in a 3mm thickness GFRP layer was demonstrated.

GFRP-Scan® algorithm, included in the ScanView® software and available for all SITAU models, allows detecting small defects in fiberglass layers with high reliability. Its effectiveness has been proved by the inspection (in field) of more than 50 blades before being installed in a wind farm.

 

5. References

 

4. Links to equipment used

 

-          SITAU-311-PRT

 

 

Facebook News

Last Tweets

Latest industry news

Wind Power News & Analysis RSS Feed

Read the latest wind industry & renewable energy companies, policy, wind farm projects & technology news, analysis on Windpower Monthly

Industrial Scanners

Aerospace Inspection Solutions

Flaw Detectors

Ultrasonic Flaw Detectors

Phased Array

Guided Wave

Pulser-Receivers

Integrated Inspection Systems

Bar Inspection Systems

Tube Inspection Systems

NDT Systems Instrumentation

 

 

 

 

Advanced NDT applications

GLASSFIBER BROKEN FIBERS

GLASSFIBER UNBOND

RAILWAY STEEL BOLTS

CASTING INCLUSIONS

AUTOMOTIVE NODULARITY

Applications

Application Notes

Applications Support

PDF Library

Video Gallery

Software Downloads

Training Academy

Obsolete Products

ISO Certifications







 


 


Update client