Perfectly integrated multi-sensor systems for laboratory applications – Thanks to special air bearing technology, integrated vibration insulation, temperature-stable scale and drive systems and a high-performance control system, the achievable length measurement errors of the highly accurate (ultra accuracy) multi-sensor coordinate measuring machine are in the range of a few tenths of a µm. The main applications are precision workpieces and 3D micro-geometries.
a) Conventional probes
b) Werth Fiber Probe®
c) Laser
d) Image processing
e) Autofocus
f) Werth 3D-Patch
g) 3D Werth Fiber Probe
h) X-ray Tomography Sensor
Non-telecentric images change sharpness and image scale as the object distance changes. With telecentric imaging on the object side (right), in contrast, the images have nearly constant scale.
a) Sensor plane
b) Virtual image plane
c) Telecentric diaphragm
In contour image processing, the image is viewed as a two-dimensional whole within an evaluation window. Contours are extracted from this image using suitable mathematical algorithms (operators). Each image point of a contour corresponds to a measurement point. The measurement points are strung together like a string of pearls. This makes it possible to detect and filter out interfering contours caused by surface structures, breakouts and dirt during measurement (contour filters) without changing the mould of the contours.
The advantage of Patented Werth MultiRing:
By combining the non-contact measuring methods of image processing and autofocus sensor, many three-dimensional measuring tasks can be solved. The features of Werth Autofocus:
Minimizing out of focus condition with a special illumination device with a small numerical aperture. Even high and rounded profile sections can be measured with great precision.
The operation of machines with a wide variety of sensors, but also the evaluation of volume data and point clouds are possible with WinWerth® in a unique combination. The Werth image processing software is based on 40 years of experience and is the foundation of probably the most powerful image processing sensors for coordinate measuring machines currently available. Optical distance sensors, conventional styluses in single-point or scanning mode, the Werth Fiber Probe®, X-ray computed tomography or machines with a combination of several sensors are all supported by the uniform concept. Measurement points, 2D images or volume data can also be conveniently evaluated in terms of geometrical characteristics or with part-to-part deviation analysis. PTB-certified evaluation algorithms ensure correct measurement results. All desired information is displayed in the graphic: CAD models with PMI data, voxel volumes, measurement point clouds, colour-coded deviation plots from 3D nominal-actual comparisons, video images, measurement and calculation elements as well as flags with nominal and actual values, tolerances and deviations. In order to meet the most diverse requirements, the software has a modular structure. Various machines can be operated, from simple measuring projectors to complex multi-axis coordinate measuring machines with multi-sensor systems or even X-ray tomography sensors.
The “intelligence” of the WinWerth® measurement software then takes over, for example, the exact determination of the object area to be captured, the selection of the geometrical element to be measured (e.g. e.g. straight line, circle, corner point) as well as the linking algorithms for determining geometrical characteristics such as distances, angles and diameters.
Measurement points or scan lines are automatically distributed on the geometry elements to be measured, e.g. as circles, cylinder surface lines, stars or spirals, taking into account the necessary travel paths. In this way, the complete measurement sequence, including evaluation, is first created offline using the CAD model or online with the minimum number of points for the respective geometry element.
The evaluation is mainly realised by PC hardware and software. In a first processing step, the image can be improved with image filters (optimising contrast, smoothing surface disturbances). This enables reliable measurements even with difficult edges and rigid scanning in incident light.
The feature tree in the WinWerth® user interface also controls the test and change mode, in which programmes can be run step-by-step and changes can be added. A text editor, available in parallel, allows experienced operators to directly enter or change DMIS programme code while teaching in programmes.
Measurement programs can be generated both online and offline using 2D or 3D CAD models. The CAD models are imported in either STEP, native CAD or IGES format. In offline mode a sensor is selected and a patch or combination of several patches is selected on the CAD model. The software computes the necessary actions for the sensor and automatically generates the corresponding segment of the program. The graphic shows the simulated measurement sequence. In online mode the procedure is similar to the offline mode, but the coordinate measuring machine immediately performs each operational step so it can be observed “live.
With 2D contour image processing and the associated image processing filters, measurements can also be taken in any cross section of the CT volume or point cloud. Among other things, this makes the measurement of workpieces made of several materials particularly easy.
With the help of section tomography or ROI tomography (ROI: Region of Interest), parts of the measuring object are measured with high resolution without having to capture the entire measuring object, e.g. , completely with high resolution using Raster Tomography, which is time-consuming and requires a lot of memory. Multi-ROI tomography offers a combination of the benefits of eccentric and sectional tomography scans. Multiple parts with high resolution can also be selected at any position in the measuring object.
A special feature of Werth is the automatic detection and measurement of burrs or chips during the measurement sequence. The result is a colour-coded deviation plot of the burr and the maximum burr length. The deviation display optionally shows only those points where the burr length exceeds the tolerance limits. The burr length along the entire burr can also be displayed numerically via analysis markers. For example, every 0.5 mm a flag is set that contains the maximum local burr length.
WinWerth® displays all the measured elements along with the selected geometrical characteristics in the 2D or 3D graphics window. The report generator summarizes the various outputs in “Office style.
| Model | VideoCheck® UA |
| General | |
| Machine Type | Highly accurate fixed bridge-type multisensor coordinate measuring machine |
| Probing System | Optical probing systems: high precision image processing sensor, highly accurate distance sensors Mechanical probing systems: fiber probe, trigger probe, scanning probe |
| Modes of Operation | Continuous-path control |
| Measuring Software | WinWerth® |
| Operating System | MS Windows |
| Measuring Range | |
| - | X = 400 mm (15.7 in.) |
| Y = 400 mm (15.7 in.) | |
| Z = 250 mm (9.8 in.) | |
| Dimensions and Masses (Min. Installation area ): | |
| Depth | 1665 mm (66.6 in.) |
| Width | 1840 mm (72.4 in.) |
| Height | 2185 mm (86 in.) |
| Machine Weight | 1600 kg (3528 lbs.) |
| Workpiece Weight mmax | 50 kg (110.3 lbs.) (optional 300 kg / 661.5 lbs.) |
| Further Performance Data | |
| Resolution of Linear Measuring System | 0.1 µm (0.000004 in.) |
| Positioning Speed, vmax | 60 mm/s |
| Acceleration, amax | 50 mm/s² |
| Supply Data** | |
| Voltage | 230 V (115 V) ±10% |
| Frequency | 48 – 62 Hz |
| Power Consumption | Max. 2500VA |
| Air Pressure | 7 – 10 bar (101.5 – 145 psi) |
| Air Consumption | 12000 Nl/h (7.06 CFM) |
| Permissible Environmental Conditions | |
| Environmental Air | Humidity 40% – 70% rel. hum., oil free |
| Air Contamination | Max. 0.05 mg/m³ (3 x 10-9 lb/cu ft) |
| Operating Temperature | 10 – 35 °C (50 – 95 °F) |
| Maximum Permissible Error MPE (extract) | |||
| For standard laboratory conditions | |||
| Tactile sensor 3D WFP 3) | PF: 0.3 µm | THN = THP: 1.5 µm | |
| – unidirectional | E1: (0.15 + L/900) µm | E: (0.25 + L/600) µm | |
| – bidirectional | E1xy: (0.25 + L/600) µm**) | ||
| Tactile sensor SP80 2) | PF: 0.6 µm | THN = THP: 1.5 µm | E: (0.5 + L/600) µm |
| Sensor image processing 1) 2) | |||
| – unidirectional | E1: (0.15 + L/900) µm | ||
| – bidirectional | E1: (0.25 + L/600) µm | E2: (0.75 + L/600) µm | E: (0.95 + L/600) µm *) |
| For standard laboratory conditions | |||
| Tactile sensor 3D WFP 4) | PF: 0.5 µm | THN = THP: 1.5 µm | |
| – unidirectional | E1: (0.25 + L/500) µm | E: (0.5 + L/350) µm | |
| – bidirectional | E1xy: (0.5 + L/400) µm**) | ||
| Tactile sensor SP80 4) | PF: 0.6 µm | THN = THP: 1.5 µm | E3: (0.5 + L/350) µm |
| Sensor image processing 1) 4) | |||
| – unidirectional | E1: (0.25 + L/500) µm | ||
| – bidirectional | E1xy: (0.5 + L/400) µm | E2: (0.75 + L/600) µm | E: (0.95 + L/600) µm*) |
| No air-conditioning required | |||
| Tactile sensor SP80 5) | PF: 0.6 µm | THN = THP: 1.5 µm | E: (0.5 + L/75) µm |
| Sensor image processing 2) 5) | |||
| – unidirectional | E1: (0.25 + L/120) µm | ||
| – bidirectional | E1: (0.5 + L/120) µm | E2: (0.75 + L/700) µm | E3: (1.5 + L/75) µm |
(Where L = measuring length in mm comparable to ISO 10360 and VDI/VDE 2617)
1) Measured with image processing sensor with 20x objective or with optical sensor with equal or better probing error
2) Measured with image processing sensor with lens 10x or with optical sensor with equal or better probing error
3) ∂ = 20 °C ± 0.25 K ∇∂ = 0.1 K/h, 0.25 K/m 3D WFP/SP80/β = 20x m ≤ mmax
4) ∂ = 20 °C ± 2 K ∇∂ = 0.5 K/h, 1 K/m 3D WFP/SP80/β = 20x m ≤ mmax
5) ∂ = 16 °C to 30 °C ∇∂ = 2 K/h, 2 K/m 3D WFP/SP80/β = 20x m ≤ mmax
*) measured with 10x objective **) measured with dual-sphere probe
Malaysia
