Micro-Epsilon UK Ltd. - PRODUCT NEWS
Factors to consider when selecting confocal displacement sensors
When selecting a non-contact confocal displacement sensor, a number of factors need to be considered, including measuring speed, resolution, type of material and surface, the operating environment and whether thickness measurements are required, says Chris Jones of Micro-Epsilon.
Although most engineers are familiar with non-contact laser triangulation sensors, many are not aware of confocal measurement technology and the benefits this measuring principle can offer for both displacement and multi-layer thickness measurement of transparent surfaces.
The confocal chromatic measurement principle works by focusing polychromatic white light onto the target surface using a multi-lens optical system. The lenses are arranged in such a way that the white light is dispersed into a monochromatic light by controlled chromatic deviation. A certain deviation is assigned to each wavelength by a factory calibration. Only the wavelength that is exactly focussed on the target surface or material is used for the measurement.
When selecting a confocal sensor, a number of factors need to be considered. These include the required measurement performance; resolution; the type of material or surface that needs to be measured; measuring speed; the type of environment the sensor must operate in; how restricted or narrow the space the sensor must operate in; and whether you need to measure the thickness of the target or material.
Resolution and spot size
Confocal sensors are often selected when laser triangulation or other optical sensors are not accurate or stable enough on the surface being measured. The confocal principle operates using a very small, constant spot size (typically 7-25 micron) through the measuring range, resulting in very stable, nanometre resolution measurements.
On polished or highly reflective surfaces and even transparent materials, for example, confocal sensors offer greater stability than on dark, diffuse materials - the exact opposite of laser triangulation sensors.
In terms of thermal stability, confocal sensors are more stable than laser triangulation or eddy current sensors. This is due to the design of the sensors, which typically comprises a cylindrical tube with a series of optical lenses. The sensor is considered "passive", as the controller and electronics are housed separately and so can be located further away from the target object, which normally means they can be mounted in a more controlled temperature environment.
Type of material or surface
The confocal principle is considered surface-independent, enabling measurements on any type of surface, both diffuse and specular - from dark, diffuse materials to highly reflective, shiny, mirrored or even transparent surfaces.
With translucent or transparent materials such as glass, a one-sided thickness measurement can be achieved using a single confocal sensor, along with the distance measurement. Also, because the emitter and receiver on a confocal sensor are arranged in one axis (i.e. the sensor measures vertically down and the beam is reflected back vertically up from the target), shadowing is avoided, which can be an issue if using laser triangulation sensors.
If you need to measure inside restricted spaces such as drilled holes, bored holes, cavities or recesses, miniature radial and axial confocal versions are now available. Some confocal sensor suppliers can offer miniature versions with diameters of just 4mm, allowing the sensor to be inserted into very tight or narrow gaps and cavities.
As confocal sensors are considered "passive", i.e. do not contain any electrical components, they are suitable for vacuum applications in semiconductor and microelectronics production. In clean rooms or vacuum environments, specific confocal sensors can be provided to suit either a low level vacuum or an ultra high vacuum with zero outgassing. As there are no electronic components inside the sensor, this means the sensors do not emit any heat radiation during operation, which in turn prevents mechanical expansion of parts inside the sensor or the target being measured. The result is a much more stable, accurate sensor.
Confocal sensors are connected to their controller (which houses all the conditioning electronics) via fibre optic cable. Cable runs can be long (up to 30m) with no degradation of the signal. And for vacuum environments, a vacuum feed-through connector is supplied.
If you need to measure the displacement, thickness or surface topography of a target material at high speeds, confocal technology is the most suitable optical displacement measurement technology. The latest confocal sensors and controllers from Micro-Epsilon, for example, achieve measurement rates of up to 70kHz using an LED light source integrated into the controller. Various interface options are available with these controllers, including Ethernet, EtherCAT, RS422 and analogue output, allowing the measurement data to be shared in real time with production and quality control systems.
Shape, size and surface topography of MEMS
Confocal chromatic sensors provide significant advantages when it comes to inspecting the shape, size and surface topography of MEMS (micro-electromechanical systems) structures during or post-production. These benefits include extremely high sensitivity and sub-micrometre resolution. The sensors can also be integrated to linear X-Y stages, machine tools or special purpose inspection systems with closed loop feedback control. Confocal sensors are capable of measuring the surface finish and groove depth of difficult materials, ranging from highly reflective, mirrored surfaces to dark, diffuse surfaces.
Compensating for difficult and changing surfaces
Traditionally, most confocal controllers perform poorly when trying to compensate for difficult and changing surface conditions, particularly in high speed surface scanning tasks. However, the latest confocal controllers from Micro-Epsilon use intelligent software algorithms based on the company's experience in the design of optical laser sensors. These algorithms enable the controller to compensate in real time for surface reflectivity, enabling users to scan surfaces very rapidly at high resolution. The controllers also provide high speed triggering that allows them to be synchronised with encoders and other motion control devices. The result is a controller that provides more stable, higher accuracy measurements, down to nanometre resolution if required.
Thickness measurement of multi-layered materials
Laminated safety glass, solar panels, flat screens and smartphone displays comprise multiple layers of different transparent materials. Measuring the exact thickness of these individual layers, as well as any air gaps between these layers, during production is a critical but physically complex process and a challenge for measurement technology.
For quality inspection and process control of manufactured transparent multi-layer materials, confocal sensors and controllers can together provide multi-peak measurement capabilities for multi-layered materials such as glass. The result is improved product quality and increased production yields for manufacturers. These confocal sensors and controllers offer faster measuring rates, improved signal-to-noise ratios, and real time surface compensation for difficult-to-measure surfaces, including mirrored surfaces. Some suppliers such as Micro-Epsilon provide software that can evaluate up to five layers by evaluating six measurement values on the boundary areas. In order to accurately determine the thickness of each layer, the controller retrieves the refractive index of each material layer from a database. Each refractive index is corrected depending on the wavelength.
Restrictions of confocal sensors
There are some limitations when using confocal technology. The operating environment for the beam path must be relatively clean and free of dust, dirt or fog, although not to clean room standards. In addition, measuring ranges are relatively small compared to other non-contact displacement technologies such as laser triangulation. The largest measurement range is typically 30mm, although sensors can still have relatively good stand off distances from the target being measured.
The controller needs to be separate from the sensor, which in some applications, can actually be a benefit rather than a hindrance. For example, where the sensor is measuring very hot targets or is mounted in a hazardous environment, the controller can be installed at a safe distance away from where the measurements are taking place. In terms of operating temperatures, confocal sensors typically withstand ambient temperatures up to 50°C, although sensors can be protected for hotter environments with enclosures, air cooling and a protective window.
Micro-Epsilon (www.micro-epsilon.co.uk) is a major global manufacturer of sensors, headquartered in Germany. The company's range of displacement sensors measure everything from to distance, position, vibration, dimensions and thickness, using both contact and non-contact measurement techniques. These techniques include 1D, 2D and even 3D laser-optical sensors and systems, eddy-current, capacitive, LVDT & inductive, potentiometric and draw-wire principles. In addition, Micro Epsilon has developed its own range of non-contact infrared temperature sensors that can measure virtually any target temperature from -40 to +3,300°C. The company also manufactures a comprehensive range of colour recognition sensors.
With more than 45 years' experience in the industry, Micro-Epsilon isn't just a sensor manufacturer. The company is highly innovative and understands the importance of providing complete solutions and support services for its customers. The firm is renowned for its expertise in consulting, development and application of industrial sensors to complex, customer-specific solutions for measurement, inspection and automation. The focus is on selling technical advantage to its customers.
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