Description:
Computed tomography (CT) is an imaging procedure that uses X–ray source to irradiate the object at different angles and 2D images at a flat panel detector are recorded. Later 3D images of the density distribution inside the object are reconstructed. The computerized tomography calculation allows the 3D reconstruction of the measured volumetric data inside the object. Up to 3 μm resolution can be achieved.
Technical specification:
X-ray source Microfocus 10 - 250 kV and Macrofocus 50 - 450 kV Focal spot 3 μm - 250 μm and 0.4 mm Size of objects diameter / Height: 1 - 600 mm / 1 - 1500 mm Max. weight of objects 80 kg Detector´s active area 410 x 410 mm2 Number of detector-pixels (optional) 1024 x 1024 / 2048 x 2048 Digitising 16 bit Resolution of detail 1μm and 0.1 - 0.3 mm Contrast < 1 % Modes of operation 3D-CT and Radioscopy Operational mode optional Region-of-Interest CT
Usage area: Medicine, biology: CT is usually used in medicine for an organic structure analysis or industry for non-destructive testing (NDT) and evaluation of object properties. Industry: non-destructive testing, visualisation of internal structures, dimensional measurements; material analysis, fault detection, assembly inspection, reverse engineering, comparison with CAD data. Science, health, space, transport industries: for construction and material analysis.
Keywords: Computed tomography, X-ray; 3D imaging; non-destructive testing; material characterization; dimensional measurements
Description: "Tescan": precise 6-axis cartesian and polar scanner with water tank
Technical specification: x, y, z, swivel, gimbal axes, turntable
Usage area: Ultrasonic non-destructive testing and measurements (metals, composites, plastic materials)
Keywords: ultrasonic measurement, non-destructive testing, imaging
Description: Stereo microscope with digital camera „Olympus“ MVX10
Technical specification: zoom range 7x-115x, maximum zoom 230x
Usage area: suitable for optical investigations and observations
Keywords: microscope, optical magnification
Description: "Tescan": Precise 11-axis cartesian and polar scanner with water tank
Technical specification: x1, x2, y1, y2, z1, z2, 2 swivel, 2 gimbal axes, turntable
Usage area: Ultrasonic non-destructive testing and measurements (metals, composites, plastic materials)
Keywords: ultrasonic measurement, non-destructive testing, imaging
Description:
Multi-channel ultrasonic phased array system „Dasel Sitau“ 128/128 (bandwidth from 0.8 up to 16 MHz, at -3 dB)
Technical specification:
Ch. 128/128 (bandwidth from 0.8 up to 16 MHz, at -3 dB)
Usage area: Ultrasonic non-destructive testing and measurements (metals, composites, plastic materials)
Keywords: ultrasonic measurement, non-destructive testing, phased array, imaging
Description:
Multi-channel low frequency ultrasonic phased array system „Dasel Sitau“ 32/128/2 (bandwidth from 0.03 up to 2 MHz, at -3 dB)
Technical specification:
Ch. 32/128/2 (bandwidth from 0.03 up to 2 MHz, at -3 dB)
Usage area: Ultrasonic non-destructive testing and measurements (metals, composites, plastic materials)
Keywords: ultrasonic measurement, non-destructive testing, phased array, imaging
Description:
High speed scanning acoustic microscope KSI-V8 for high-frequency ultrasonic studies in water to investigate the internal structure of various metals and their alloys, carbon and glass-fibre-reinforced composite materials, metal composites, plastics and their alloys, and to search for internal defects. Also for the study of the internal structure of electronic components and biological objects.
Technical specification:
up to 500MHz with scan field of 400mm × 400 mm with special set of transducers (up to 230MHz)
Usage area: for high frequency applications and measurement in water (metals, composites, plastic materials, microchips, biological objects)
Keywords: ultrasonic microscope, high frequency, imaging, non-destructive testing, material characterization
Description:
Multi-channel Eddy current / ultrasonic phased array system „Olympus Omniscan Mx“
Technical specification:
Eddy current ch. 32 (operation frequency from 20 Hz up to 6MHz, bandwidth 8Hz - 5kHz), Ultrasonic phased array ch, 128, bandwidth from 0.75MHz up to 18MHz (-3dB)
Usage area: Eddy current / ultrasonic non-destructive testing and measurements
Keywords: Eddy current / ultrasonic measurement, non-destructive testing, phased array, imaging
Description:
Multi-channel ultrasonic phased array system „Dynaray“ 64/256 (bandwidth from 0.20 up to 25 MHz, at -6 dB)
Technical specification:
Ch. 64/256 (bandwidth from 0.20 up to 25 MHz, at -6 dB)
Usage area: Ultrasonic non-destructive testing and measurements (metals, composites, plastic materials)
Keywords: ultrasonic measurement, non-destructive testing, imaging, phased array
Technical specification:
The system is versatile, capable of detecting and measuring electromagnetic radiation and acoustic signals;
Capable of detecting partial discharges and locating without disconnecting the subject from the mains;
Ability to measure partial discharge noise inside the installation;
Acoustic input channel frequency band 10 kHz...500 kHz at -3dB;
High frequency input channel frequency 50...1000 MHz;
High-frequency channel accuracy ±100 kHz;
High-frequency input channel impedance 50 Ω;
Option to connect an external parabolic antenna;
Capable of detecting partial discharges from peak and average values;
Measurement modes compatible with: continuous, average, peak, differential;
Memory - internal with possibility to connect external memory;
USB interface;
Power supply from Li-Ion batteries;
Battery life >6 h;
Data file format XML;
Usage area: 1. Applied research on non-contact non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, hydro and wind), aerospace 2.Prototype development of measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and bulky engineering structures
Keywords: Non-contact measurements, electromagnetic radiation, non-destructive testing
Technical specification:
The generator has a maximum output of 3000 W;
Frequency of the generator is variable within the range 20 kHz ... 100 kHz;
Amplitude control - constant and adjustable according to load;
Possibility to adjust amplitudes using analogue signals,
The device is equipped with a clamp with a specialised ultrasonic transducer for forming the ultrasonic effect in cylindrical objects (pipes, containers) with a diameter of 220 mm.
Usage area: 1. Applied research on the physical-mechanical properties of materials, their changes and the detection of internal defects, using non-destructive ultrasonic methods of materials science, diagnostics, measurement and impact 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the use of ultrasonic diagnostics and exposure techniques in the pharmaceutical and biotechnology sectors 4.Development of prototypes of ultrasonic quality control and exposure systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing, monitoring and ultrasonic exposure systems to ensure the safety of industrial facilities and bulky engineering structures 6. Prototyping of ultrasonic transducers for medical, technical diagnostics and industrial applications 7.Technical feasibility studies for the application of new non-destructive ultrasonic testing, measurement and ultrasonic exposure techniques for quality control of industrial products and monitoring of production processes
Keywords: Action ultrasound, cavitation, ultrasonication, process intensification
Technical specification:
Mobile active thermal imaging system for non-destructive testing and defect detection of composite, porous materials;
Incandescent lamps for illumination;
The system supports lock-in, pulsed and transient methods;
Thermal imaging detector resolution 640 x 480 active pixels;
Thermal imager spectral range 7,5 ... 13 µm;
Thermal sensitivity 30 mK;
Field of view 50° x 38°;
Maximum frequency of the thermal imager 250 Hz;
The control unit has 1 analogue input and 2 analogue outputs;
Control unit has integrated oscillator, frequency range 0,001 Hz ... 10 kHz;
A halogen lamp shall be used to heat the surface of the test objects;
The heat-emitting illuminator shall be compatible with the control unit and the software.
The power of the heat-emitting luminaire shall be 2000 W;
Luminous flux of the heat-emitting luminaire 28000 lm; Colour temperature of the heat-emitting luminaire 3200 K;
The system shall be controlled by software;
Usage area: 1. Applied research on the physical-mechanical properties of materials, their changes and the detection of internal defects, using non-destructive material science, diagnostic and measurement methods 2.Development of prototype thermographic quality control systems for the monitoring of technological processes in production 3.Technical feasibility studies for the application of new non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Thermography, thermal imaging, non-destructive testing
Technical specification:
Coating thickness measurement on magnetic and non-magnetic metals;
Coating thickness measurement up to 3000 μm on magnetic substrates and up to 3000 μm on non-magnetic substrates;
Units of measurement: μm and mm;
Measurements in 1 second - 1 measurement;
Measuring resolution 1 μm for measurements up to 999 μm and 10 μm for measurements above 1000 μm;
Tolerance ±3 % + 2 μm;
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic methods in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: non-contact testing, non-destructive testing, ultrasonic measurements, thickness measurements
Technical specification:
The system is compatible with phased arrays with a maximum of 64 active transducers.
Number of channels 64.
Number of channels for real-time signal focusing 64.
Full focus: ability to assess direct propagation, partial reflection, full reflection.
Focus modes during full focus: longitudinal, transverse, converted waves.
Scanning modes A/B/C/D images, echodynamic image, 3D image, top view, side view.
Generator pulse size from 30 ns to 1250 ns.
Generator pulse voltage from 12 V to 200 V, step 1 V.
Input impedance of the signal measurement transducer shall be 50 Ohm.
The frequency range of the signal measurement transducer shall be 0,6 MHz to 25 MHz.
Gain of the signal recording receivers shall be 120 dB, 0,1 dB step.
Digitiser parameters:
Number of channels 64;
Amplitude resolution 16 bits;
Maximum frequency not less than 100 MHz;
Interfaces USB, external trigger input, encoder input.
Ethernet remote data transmission capability.
Standard memory 256 GB.
Trigger modes compatible with time domain, event, encoder signal.
Software - Preparation of test report form, generation of scan images (A/B/C/D/3D).
Touch screen 10.4"
Screen resolution 1024x768 pixels.
Protection class IP66.
Operating temperature -10 °C ... +45 °C.
Battery life up to 6 hours.
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Ultrasonic non-destructive testing, phased arrays, focusing
Technical specification:
Measurement modes through the coating:
(a) measurement of metal thickness and coating thickness with a single back wall reflection signal;
(b) time interval between two consecutive wall reflection signals, eliminating paint or coating thickness.
Has a two-element transducer measurement mode - measures the time interval between the exact delay after pulse excitation and the first reflection signal.
The following single element transducer measurement modes are available:
Mode 1: measures the time interval between the excitation pulse and the back wall reflection;
Mode 2: measures the time interval between the delay line reflection signal and the back wall reflection signal (using delay line or immersion transducers);
Mode 3: measure the time interval between the subsequent reflections from the back wall and the first reflection from the surface (using either sweep-line transducers or immersion transducers)
Ability to measure oxide layer thicknesses;
Measurable thickness range: from 0.080 mm to 635.00 mm depending on material, transducer, surface conditions, temperature.
Ultrasonic velocity in the material range: 0.508 mm/μs to 13.998 mm/μs.
Resolution optional: Low: 0.1 mm; Standard: 0.01 mm; High resolution: 0.001 mm;
Transducer frequency range: Standard: 2.0 MHz to 30 MHz (-3 dB)
High resolution (optional): 0.50 MHz to 30 MHz (-3dB)
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic methods in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: non-contact testing, non-destructive testing, ultrasonic measurements, thickness measurements
Technical specification:
Ultrasonic microscope module:
- Frequency band 50-450 MHz;
- 14-bit analogue-to-digital converter; digitising frequency 2 GHz;
- Averaging capability;
- Pulse repetition rate 200 kHz;
- Broadband excitation capability.
Mechanical scanning unit:
- xy-scanner, scanning area dimensions 10 mm;
- Scanning pitch 1 μm;
- Capable of mounting an optical microscope.
Acoustic ruler:
- Close range and wide angle, frequency 400 MHz, ultrasonic and photoacoustic capability.
Photoacoustic excitation module:
Laser compatible with 532/1064 nm wavelengths;
- Pulse length <2 ns, pulse energy >30 μJ;
- Optical fibre used for photoacoustic imaging.
Optical microscope module:
- Optical microscope oriented vertically, capable of handling reflected and transmitted light; LED illumination, interchangeable objectives.
Specialised software has the following analysis capabilities:
- Recording of scanning point information, acquired image and RF-signal data (3D-volume);
- Image export;
- Analysis by estimating amplitude, dispersion, propagation time values;
- Analysis based on defined thresholds;
- Analysis of geometry, layer thicknesses, ultrasonic velocity and impedance changes.
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic methods in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: ultrasound microscopy, non-destructive testing, biomicroscopy, photoacoustics
Technical specification:
The device is designed to search for debonding defects in composite and cellular structures.
The operating modes of the device are: resonance analysis, impedance analysis and direct
pass.
Frequency range: 1-50 kHz (pulse mode) and 1-100 kHz (variable frequency mode);
For impedance analysis, frequency range 1-500 kHz;
Gain from 0 dB to 70 dB
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic methods in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: non-destructive testing, composite testing, internal defect detection
Technical specification:
Portable X-ray fluorescence analyser with integrated Rhodium anode;
Fluorescence excitation source: 4 W minimum, more than 35 kV
X-ray source, allowing analysis
the following chemical elements: Mg, Al, Si, P, S, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn,
W, Hf, Ta, Re, Pb, Bi, Zr, Nb, Mo, Pd, Ag, Cd,Sn, Sb
Detector type: large area SDD (silicon drift detector);
Integrated collimator with a choice of 3 mm or 10 mm measuring points;
Elemental detection limits are expressed over a test time of up to 60 seconds per beam in automatic mode, during which the concentration of the elements to be analysed is deduced.
Usage area: 1. Determination of physical-mechanical properties of materials, their changes by X-ray fluorescence analyser and applied research on detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aviation and space sectors 3.Applied research on the application of non-invasive diagnostic methods in medicine 4.Development of prototype quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Non-destructive testing, X-ray fluorescence analyser, material composition analysis
Technical specification:
Polytec PSV-500-3D non-contact laser measuring instrument for recording spatial displacements caused by ultrasonic waves in various objects and structures, scanning of the laser beam in space, recording and analysis of 3D displacement components (horizontal - vertical):
Measurement of 3D spatial displacement components by laser method without contact sensors;
Ability to investigate a wide range of objects with smooth, rough and porous surfaces;
Measured spatial displacements with a frequency range of at least 0 Hz to 25 MHz;
Capable of scanning large and moving objects, with a velocity range of not less than 3 mm/s to 30 m/s;
A decoder operating frequency of at least up to 25 MHz;
Scanning head resolution of not less than 0,01 ;
Scanner resolution of not less than 0,002°;
Scanning head laser class compatible with class 2, measuring laser wavelength compatible with 1550 nm, power not more than 10 mW, minimum scanning distance not more than 125 mm, maximum scanning distance not less than 100 m;
Scanning angle not narrower than 50° x 40°, scanning speed not less than 30 pixels per second, ability to scan objects from a few mm² up to several m²;
Wavelength of the laser used for aiming compatible with 520 nm;
HD video camera;
Distance sensor for determining the dimensions of the object to be measured, with an accuracy of at least ±2,5 mm at a distance of 1,5 m;
Laser frequency stabilisation module for all scanning heads;
Scanning laser synchronisation module to align all 3 scanning heads;
FFT line count of at least 12800 lines;
Signal generator output channels: ±10 V, ±100 mA, maximum frequency not less than 25 MHz;
Signal digitising and recording unit, integrated 4-channel 16-bit A/D converter;
Automatic scanning and software control of the surfaces of the test objects
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Non-contact laser ultrasonic wave reception, laser vibrometer, interferometry, ultrasonic measurements
Technical specification:
The system consists of a main module and measuring sensors with different diameters.
The system consists of 24 transmission channels and 24 measurement channels.
The excitation signal shall have a peak amplitude of 300 V.
Maximum time domain length up to 1000 ms.
Measured signal gain range 1 dB - 120 dB, step 1 dB.
Instrument battery life >10 hours.
OLED display, Wifi, Ethernet.
Has an integrated air pump and a self-test system to automatically check if everything is working properly.
Includes software that automatically selects the test frequency depending on the geometry of the test tube.
It has the capability to perform longitudinal and rotating wave tests.
Available sensor diameters from 6" to 24" diameter.
Boltless mounting with quick couplers.
It has the ability to test pipes from the outside and inside.
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Ultrasonic non-destructive testing, guided waves, pipelines, focusing
Description:
Recording of small spatial displacements caused by propagating ultrasonic waves at high frequencies with a non-contact laser measuring instrument
Technical specification:
Laser spatial displacement measurement with a maximum frequency of up to 2.4 GHz;
Maximum measurement time 1,963 ms;
Digitisation rate 40 GSa/s;
Amplitude resolution 8 bits;
Offset-amplitude resolution 1,5 pm at 2,5 kHz;
Working distance with standard lens 20 mm;
Number of adjustable axes of the table top of the object to be measured 2: X and Y;
Test area 200 mm x 200 mm;
Table top adjustment is motorised with a maximum displacement of ±100 mm;
Table top movement speed up to 9 mm/s;
Adjustment repeatability ±0,5 μm;
Control lever used for table top positioning;
Maximum weight of the object to be measured up to 10 kg;
Data is read by an oscillograph and transmitted to a computer;
Oscillograph bandwidth 2,5 GHz, sampling rate 40 GSa/s, number of input channels 2;
The instrument is automated - controlled by software installed on the computer;
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Non-contact laser ultrasonic wave reception, laser vebrometer, interferometry, ultrasonic measurements
Technical specification:
Number of batteries 2;
Maximum take-off speed 5 m/s;
Maximum landing speed 4 m/s;
Maximum flying speed 61,2 km/h;
Capable of flying in maximum possible winds up to 15 m/s during flight;
Maximum flight time 55 min;
Drone control frequencies compatible with 2.4 GHz and 5.8 GHz;
Maximum signal range 7 km;
Capable of transmitting images directly to a ground station;
Possibility to control the camera by remote control;
With flight capability according to a predefined route;
Thermal imaging camera:
Thermal imaging camera detector resolution 640 x 512 pixels;
Field of view 25° x 20°;
Minimum focusing distance 30 cm;
Digital zoom 8x;
Spectral range 7.5 ... 13.5 µm;
Detector scan rate 30 Hz;
Thermal sensitivity 50 mK;
Measurable temperature -40 °C ... + 550 °C;
Option to store files on a memory card;
File formats compatible with JPEG, TIF, R-JPEG;
Video storage formats compatible with MP4, MOV;
Digital camera:
Camera resolution 12 megapixels;
Field of view 57,12° x 42,44°;
8x digital zoom;
Photo storage format compatible with JPEG;
Video storage format compatible with MP4, MOV;
Video resolution 4K Ultra HD;
Data stored on memory card,
Usage area: 1.Applied research on non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, hydro and wind), aerospace 2.Prototype development of measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and bulky engineering structures
Keywords: thermography, drone, non-destructive testing
Technical specification:
Parameters to be measured: frequency, acoustic field pressure, steady-state cavitation pressure, transient cavitation pressure;
Averaging intervals 1 ... 60 sec.
Storage of measurement results: spectrum, waveform, value;
Sensor frequency from 20 kHz to 1200 kHz;
Maximum operating temperature up to 70 °C;
Sensor suitable for use in media with pH 4 to 12;
Sensor diameter 3 mm;
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Cavitation, exposure ultrasound, acoustic intensity measurement
Technical specification:
Thermal imager detector pixel count 1024 x 768;
Detector type: non-refrigerated microbolometer;
Thermal sensitivity <20 mK at +30 °C;
Lens 28° x 21°;
Minimum focal length 40 cm;
Minimum focal length 36 mm;
Spatial resolution with 28° lens 0.47 mrad;
Automatic lens recognition and calibration according to the lens used;
Thermal imager frame rate 30 Hz;
Automatic and manual focus;
Digital zoom 8 times;
The thermal imager is equipped with a special algorithm for noise filtering;
Detector detects wavelengths of 7.5 ... 14 μm;
The thermal imager has a touch-sensitive colour display;
Thermal imager with automatic image orientation (horizontal/vertical);
The device shall have an integrated viewfinder;
Has an integrated digital video camera with a resolution of 5 megapixels;
It has a mode that allows you to see the clear outline of objects and to read notes in the dark;
Temperature measurement range -40 °C ... +2000 °C;
Accuracy ±1 °C over a range of +5 ... +150 °C;
Accuracy ±2 °C or ±2 % over the range +25 ... +2000 °;
Usage area: 1. Applied research on the physical-mechanical properties of materials, their changes and the detection of internal defects, using non-destructive material science, diagnostic and measurement methods 2. Applied research on non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aviation and space sectors 3.Applied research on the application of thermographic diagnostic methods in medicine 4.Development of prototypes of thermal imaging quality control systems for monitoring technological processes in production 5.Development of prototypes of measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large engineering structures 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Thermal imaging, thermography, non-destructive testing, non-contact testing
Technical specification:
Display 8" LCD;
100 V-240 V, 50/60 Hz, stationary power supply;
Lithium-ion battery for 150 min. continuous operation;
Video output standard: HDMI;
5 x digital zoom;
16 brightness levels;
Adjustable gain;
Dynamic Noise Reduction;
3 levels of brightness and saturation adjustment;
Control of the surveillance image: left, right, down and up;
SD memory card
Photo resolution H768xV576;
JPEG photo recording format;
Video recording resolution H768 x V576;
Video format MPEG4;
Interchangeable probes;
IP65;
Operating environment - 10°C to 40°C; Display 8" LCD;
Stationary power supply - 100 V-240V, 50/60 Hz;
Lithium-ion battery for 150 min. continuous operation;
Video output standard: HDMI;
5 x digital zoom;
16 brightness levels;
Adjustable gain;
Dynamic Noise Reduction;
3 levels of brightness and saturation adjustment;
Control of the surveillance image: left, right, down and up;
SD memory card
Photo resolution H768xV576;
JPEG photo recording format;
Video recording resolution H768 x V576;
Video format MPEG4;
Interchangeable probes;
IP65;
Operating environment from - 10°C to 40°C;
Indicators for the flexible part of the videoscope and the optical adaptors:
Length 2 metres;
Diameter: 6 mm;
Outside - durable tungsten braid;
2 level high temperature warning indicator;
Tilt control angle 150 degrees;
LED illumination;
Interchangeable optical adapters;
Direct view adapter viewing angle 120°, depth of field from 2 mm;
Side-view adapter 120° field of view, depth of field from 1 mm;
80° field of view of the Direct Image Adaptor, depth of field from 9 mm to ∞;
Side-view adaptor field of view 80°, with a field of focus from 15 mm to ∞;
For stereo measurements, the field of view of the Direct Image Adapter is 60°/60°, with a focus from 5 mm to ∞;
Stereo side-view adapter with a field of view of 60°/60°, focus of 4 mm to ∞;
Measurement functions:
Line measurement (using a reference length, the length of the object can be measured);
Distance between two points;
Perpendicular distance from a point to a line marked by the user;
Perpendicular depth/height distance from a point to a user-defined plane;
Calculation of the position and area points;
Usage area: 1. Applied research on non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, hydro and wind), aerospace 2.Prototype development of measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and bulky engineering structures
Keywords: Videoscope, internal cavities, visual inspection
Technical specification:
Intopsys LUKS-1550-TWM
The system operates on a laser - non-contact principle;
The system is designed to excite and receive ultrasonic waves in a non-contact manner;
Frequency band for DC channel 0 - 50 kHz;
Frequency band for AC channel 25 kHz - 125 MHz;
Surface displacement sensitivity 2 x 10-7 nm RMS (W/Hz)1/2;
Number of optical inputs for generating and measuring signals - 2;
Measuring head with universal base;
Measuring aperture 25 mm;
Measuring point diameter 200 μm;
Pulse frequency up to 10 MHz;
Analog module with amplifier for conversion of surface roughness to surface propagation velocity;
Low-noise amplifier frequency band 0,1 MHz to 1 GHz;
Detectable frequency 1 MHz - 20 MHz;
Pulse width 10 ns;
Pulse repetition rate 20 Hz;
2 D motorised mechanical scanning platform with stepper motor;
Option to mount the platform vertically;
Maximum scanning distance 25 cm;
Step resolution 5 μm
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Non-destructive testing, laser excitation, non-contact ultrasonic wave excitation
Description:
Immersion NTR acoustic intensity measurement system (AIMS) that allows measuring and mapping of acoustic fields in liquids
Technical specification:
Sensitivity of the membrane type hydrophones 100..160 nV/Pa, bandwidth 0.5-45 MHz. Sensitivity of the needle type hydrophone 170 nV/Pa, bandwidth 1-10 MHz.
Usage area: Suitable for acoustic intensity measurement in a field of medical imaging, pulsed and CW Doppler, therapeutic devices and industrial ultrasound
Keywords: acoustic pressure, immersion measurements, intensity
Technical specification:
Laser measurement of 2D spatial displacement components without contact sensors;
Ability to examine a wide range of objects with smooth, rough and porous surfaces;
Measured spatial displacement frequency range from 0 Hz to 25 MHz;
Decoder operating frequency up to 25 MHz;
Capable of scanning large and moving objects, speed range from 1 mm/s to 12 m/s;
Scan head resolution 0,01 ... 18 μm/s*√Hz-1;
Usage area: 1. Applied research on physical-mechanical properties of materials, their changes and detection of internal defects using non-destructive ultrasonic methods of materials science, diagnostics and measurement 2. Applied research on non-destructive ultrasonic testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, water and wind), aerospace 3.Applied research on the application of ultrasound diagnostic techniques in medicine 4.Development of prototypes of ultrasonic quality control systems for monitoring technological processes in production 5.Development of prototypes of ultrasonic measurement, non-destructive testing and monitoring systems to ensure the safety of industrial facilities and large-scale engineering constructions 6. Prototyping of ultrasonic transducers for medical and technical diagnostics 7.Technical feasibility studies for the application of new ultrasonic non-destructive testing and measurement methods for quality control of industrial products and monitoring of production processes
Keywords: Non-contact laser ultrasonic wave reception, laser vibrometer, interferometry, ultrasonic measurements
Description:
Technical feasibility studies for the application of new non-destructive ultrasonic testing and measurement methods for quality control of industrial products and monitoring of production processes. For example, studies on the development and implementation of a measurement method to improve the production process.
Keywords: Monitoring, ultrasonic non-destructive testing, manufacturing, industry, quality control, products
Description:
Characterisation of ultrasonic transducers by measuring frequency characteristics, emitted field parameters (intensity, pressure), width of the diagram, area of maximum field intensity
Keywords: Research, ultrasonic transducers, transducer characteristics
Description: null
Keywords: Prototypes, safety, industry, monitoring, ultrasonic measurements
Description:
Technical feasibility studies on the application of new ultrasound diagnostic methods in medicine to improve the informativeness of early diagnosis. For example, improving the quality of the early diagnosis process by combining several non-invasive diagnostic methods.
Keywords: Technical feasibility study, diagnosis, medicine, ultrasound
Description:
Applied research on the use of ultrasound diagnostic methods in medicine. Examples of applications: early diagnosis of skin and eye tumours, measurement of biological fluid properties
Keywords: Medicine, research, diagnostic, ultrasound
Description:
Applied research into the physical-mechanical properties of various metallic, plastic, composite, etc. materials, their changes and the detection of internal defects, using non-destructive ultrasonic methods of materials science, diagnostics and measurement
Keywords: Diagnostics, ultrasonic methods, non-destructive testing, defects detection, material characterization, multi-layered composites, metals, plastics
Description:
Applied research on ultrasonic non-destructive testing methods for the prevention of technological accidents in the oil and gas industry, transport (railways, bridges), energy (nuclear, thermal, hydro and wind), aerospace and aviation sectors. For example, the study of the impellers of wind turbines to detect internal defects, the study of the corrosion of the bottom of fuel tanks, etc.
Keywords: Ultrasound, non-destructive testing, testing, accident prevention, industry, aviation, energy, transport, wind energy, railways, internal defects
Description:
2D and 3D X-ray microtomography studies of the internal structure of various objects made of metals and their alloys, carbon and glass-fibre reinforced composite materials, metal composites, plastics and their alloys and other materials.
Keywords: X-ray microtomograph, non-destructive, testing, material characterization
Description:
Technical feasibility studies for the development, validation and standardisation of new non-destructive testing methods and systems. For example, descriptions of procedures for the application of new measurement methods, etc.
Keywords: Non-destructive testing, certification, diagnosis, technical feasibility study
Description:
Qualitative study of solar cells by ultrasonic methods
Keywords: Solar cells, qualitative research, ultrasonic methods
Description:
Photoelectric module quality study by assessing polycrystal delamination
Keywords: Photoelectric module, quality testing, polycrystal deposition
Description:
Prototyping of ultrasonic quality control systems for monitoring technological processes in production. Examples of applications: viscosity and density measurements of liquid plastics under production conditions, measurements of changes in layer thicknesses of multilayer plastic pipes in production, measurements of changes in density of ceramic tile blanks, investigation of food blanks.
Keywords: Prototypes, ultrasound, monitoring, technology, manufacturing
Description:
Prototyping of ultrasonic transducers for medical and technical diagnostics. For example, specialised ultrasonic transducers (not available on the market) for air gap analysis of composites, high temperature measurements
Keywords: Prototypes, medicine, transducers, ultrasound