Under the motto of “Intelligence in Production,” solutions were presented at EMO Hannover 2013 that efficiently integrate new information technologies. The focus was on innovations that automate, simplify, or enhance the efficiency of the work sequences involved. The showcase of path-breaking production technologies has created the foundation for maintaining competitiveness against globalized competition. One general trend is the incorporation of styling and operator-friendliness. Emulating smartphones, numerous machinery control systems now feature a touch-screen. In conjunction with the design of other equipment, this combines to produce an attractive visual appearance.
From a technical viewpoint, numerous solutions are motivated by currently expanding industrial sectors, like the aircraft industry and energy utilities. The titanium- and nickel-based alloys used, titanium aluminides or carbon-fiber composite materials require appropriate tools, machinery and machining strategies. The energy turnaround goes hand in hand with a rising demand for systems designed to use regenerative energies. Efficient machining of the large-dimensioned components requires appropriate equipment. In order to improve efficiency of the production process, new manufacturing technologies like 3D printing are being progressively integrated into ongoing production operations. The spectrum of structures that can be manufactured is significantly extended. However, there are still limitations to these processes if quality requirements are to be complied. To enable conventional machining to be performed more efficiently the pieces of equipment concerned are purposefully modified. One example is the use of carbon-fiber composites for structural components of machines or as part of tools. Thanks to their lighter weight, the better damping properties and the higher rigidity of this material, the performance capabilities of the equipment, and thus the productivity of the production process, can be enhanced.
Examples are presented below of the trends and issues on which production technology is focusing.
Enhanced Operator-Friendliness by Using Innovative Information Technologies
Many EMO Hannover exhibitors showcased solutions that prioritized operator-friendliness. Modeled on smartphone and tablet technologies, concepts were on show that significantly facilitate control of the equipment. With Celos, DMG / Mori Seiki Europe Dübendorf, Switzerland premiered an operator control level with a touch-screen. The processor behind it can be embedded in the production planning function. In this way, CAD data can be viewed directly, and changed at will. Liebherr-Verzahntechnik GmbH, Kempten, Germany, a manufacturer of gear-cutting machines, premiered a new, intuitive system for operator control and for simplified job set-up of its machines. Touch-based operator control and plausibility checks, plus direct graphical depiction of the tools selected by the operator, enabled shorter job changeover times and avoided errors.
Complete Machining of Workpieces for Enhanced Productivity
The aim here is to perform several different machining operations on a single machine, so that the changeover times are reduced and accuracy levels improved. WFL Millturn Technologies GmbH & Co. KG from Linz, Austria presented a machine that enables its users to execute not only turning, milling and drilling operations, but also deep drilling, grinding, and honing. In addition, metrological technologies can be used for taking in-process measurements. In addition, a capability has been integrated for internal turning of large drilling depths as a new process, making for a shorter path and a higher surface quality of the boreholes created.
For rotary transfer machines, too, complete machining is the watchword. Mikron SA from Agno, Switzerland presented a rotary transfer machine with twelve stations, in the shape of the NRG-50. Three machining units can be integrated at each station. A total of 30 units can be in operation simultaneously; the maximum number of tools is 96. Six-side machining creates a complete-machining capability. Thanks to the modularized construction, the machine can be adapted to suit different series-production requirements.
Another example for the integration of several machining operations on a single machine comes from MAG IAS GmbH in Göppingen, Germany. In the shape of the Specht 600 Duo, a CNC machine featuring a double spindle and integrated honing technology was showcased, designed in particular for machining motors. So far, in most cases dedicated machines are used for honing operations.
Flexibility for Large Machines
The issue of flexibility is becoming progressively more crucial for large machines. The aim here is to reduce set-up times, avoid re-clamping the tools, and automate the work sequences involved. For machining boreholes with relatively large diameters using the BTA (Boring and Trepanning Association) process, a deep-drilling procedure for creating boreholes with a large length-to-diameter ratio, or a combined peeling and burnishing process, not much optimization has been accomplished so far. In order to speed up the change-over process, Ecoroll AG from Celle, Germany, premiered what it says is the first quick-change interface for this category. In this concept, the tool is moved into the device without rotation and clamped by turning it 40°. Compared to conventional BTA and ejector threads, this innovative interface enables the tool changeover routine to be automated. This is particularly useful when several different processes, like drilling, peeling, and burnishing cannot be performed in combination.
New Developments in Turning Operations
In the case of turning operations, due to the relatively simple kinematics of the process concerned, there are limits to the amount of optimization achievable. In order to upgrade efficiency, new concepts are needed for minimizing changeover times. Weiler Werkzeugmaschinen GmbH, Emskirchen, Germany, presented a 4-path lathe fitted with automatic cycle control. In this way, the tool slide and the steady rests for supporting the work piece can be moved independently of each other, enabling a solution that assures high precision even for large-size work pieces. The machine is in its standard version constructed with a peak width of 12m, which can be extended using modularization up to a length of approximately 30m. In order to upgrade productivity levels for machining ships’ crankshafts, Weingärtner Maschinenbau GmbH from Kirchham, Austria, premiered a mill-turning machine. Thanks to a traversing and swiveling milling head, this model is also able to machine the bearing seats for the connecting rods.
Machine Tools with Parallel Kinematics
At roughly the turn of the millennium, the use of parallel kinematics in production technology was being intensively researched and discussed by reason of its inherent improvement potentials compared to conventional machines with serial kinematics. So far, however, machines featuring parallel kinematics have not been able to meet the high expectations of their users. Willemin-Macodel SA from Delémont, Switzerland, a manufacturer of high-precision components for the watch industry, the medical technology producers, and the aerospace sector in particular, exhibited a new machining center with parallel kinematics, in the shape of the 701S. The machine’s concept is essentially based on delta kinematics driven by three linear motors with play nearly eliminated, thus actuating the machine’s translatory degrees of freedom. According to the manufacturer, dynamics and accuracy can be significantly improved compared to his serially driven machines, thus reducing the machining time required by a factor of five.
Conventional Machines from Asia
Conventional lathes and milling machines, which are an absolute necessity for teaching and training organizations, were on show at EMO Hannover. Almost all these machines come from Asian countries, which is why not only the manufacturers themselves are represented but also European companies that import machines from Asia. Kami GmbH from Isernhagen, Germany, showcased its machinery portfolio, which is manufactured by Chinese firms. The machines are imported, and customized to suit each purchaser’s requirements. Service support is provided directly by Kami.
Following the last EMO Hannover in 2011, there were reports of planned joint ventures between Chinese and German manufacturers. One result was presented by Shenyang Machine Tool Group from Shenyang, China. The Viva Turn horizontal CNC turning center has been designed for the European market, and developed by German engineers at the development center of Schiess Tech GmbH in Berlin. The machine is manufactured in China, and according to the vendor, provides high-speed machining with good levels of both accuracy and reproducibility.
Dry-Machining Still a Topical Issue
Dry-machining continued to be a significant issue at EMO Hannover 2013. New solutions were spotlighted in different categories. The tool manufacturer botek Präzisionsbohrtechnik from Riederich, Germany, premiered single-lip deep-drilling tools developed specifically for machining with minimal-quantity lubrication. These high-performance drills are offered in a diameter range of between 2mm and 12mm. Gühring OHG from Albstadt, Germany, exhibited a test rig for tools with a minimal-quantity-lubrication feature. In this test rig, particularly, the response time up to the first aerosol exit and up to a constant aerosol flow can be determined. In addition, there is an option for checking how large the oil quantity is and whether this value remains constant over the entire process time. The company offers its customers a corresponding check routine for minimal-quantity-lubrication tools as an extra service.
Starrag AG from Rorschacherberg in Switzerland, and Walter AG from Tübingen, Germany, showcased their jointly developed solution for cryogenic process cooling. Cooling by means of CO2 snow offers numerous advantages in terms of coolant feed compared to the previous nitrogen-based cooling. During the feed operation, until it exits from the nozzle near the blade, the CO2 is at room temperature. This means the concept can be retrofitted to existing machines. Typical applications for cryogenic machining operations include processes that hitherto have been carried out in dry mode, and in which productivity can be increased by using this innovative form of cooling. In addition, extended useful lifetimes are possible when handling difficult-to-machine materials like titanium-based alloys.
Using Carbon-Fiber Composites in Machine Tools and Tools
The xperion components GmbH & Co. KG company from Laudenbach, Germany, showcased tools and machine components made of carbon-fiber composites at EMO Hannover, exemplified by an optimized grinding disk. The preceding model had a fabric-like structure. The new disk is made of thin, oriented layers, thus further significantly increasing its rigidity. The radial termination is implemented as an annular rigid profile. In the category of turning, a drill rod was presented for internal turning, with which the length-to-diameter ratio has been increased from 3.5 to 4.6 by using carbon-fiber composites. In the category of machine components, carrier components were exhibited with which the weight has been reduced by 25% compared to conventional solutions. In addition, carbon-fiber composite components exhibit higher rigidity and better damping properties. Thanks to an innovative expansion compensation concept, a solution was presented for guide ways: these are made of metal on a carbon-fiber composite base, and can expand as necessary when subjected to thermal stress.
At EMO Hannover, Werkzeugmaschinen & Automation GmbH from Magdeburg exhibited a machine for which the Z-slide was manufactured from carbon-fiber composites. Compared to a slide made of aluminium, the weight has been reduced by 45%. This weight saving can be utilized for a higher dynamic of the linear axes. Besides higher productivity, the energy consumption has simultaneously been reduced.
Machining Carbon-Fiber Composites
Machining plastics is particularly problematic because of the health-hazardous dust produced. Jakob Lach GmbH & Co. KG from Hanau, Germany, presented a PCD continuous-drilling tool for machining carbon-fiber composites, glass-fiber composites or thermosetting plastics fitted with an internal extraction feature. The dust particles containing glass fibers or carbon are, says the vendor, effectively removed from the process, eliminating the risk for humans and the environment.
Using Laser Technologies
The laser technologies offer options for both ablating and depositing material. Acys Lasertechnik GmbH from Kornwestheim, Germany, showcased a process for creating chip-breaker geometries at tools. The chip-breakers are very difficult to produce individually or as small series by conventional methods. With this laser technology, any defined chip groove geometries can be created. In addition, there is an option for rounding off cutting edges with the laser. This process is currently being developed for series production, and could replace conventional processes like abrasive blasting.
In 3D printing technology, material is deposited using lasers. Layer by layer, powder is applied, and melted onto the component concerned by the laser. EOS GmbH from Krailling, Germany, outlined the possibilities unveiled by this technology in a presentation given under the aegis of the congress on “New Production Technologies in the Aerospace Industry.” Complex components can be manufactured whose structure cannot be produced by metal-cutting. It is predicted that in future around 50% of a turbine’s components will be additively manufactured, with projected weight savings of 450kg in a turbine weighing 2,700kg.
The laser is also used for supporting conventional machining processes. Fraunhofer IPT from Aachen and tool manufacturer Rineck Maschinenbau GmbH from Marienfeld, Germany, presented a milling tool in which the material concerned is warmed up directly in front of the blade using a laser. Thermal softening of the material reduces the process forces required for subsequent milling of silicon nitride ceramics by 90%, and for machining the nickel-based alloy Inconel 718 by up to 60%. A real-time control system is used to synchronize the laser irradiation with the tool engagement, so that only the material being machined is softened, and the possibility of damage to the rest of the material can be ruled out.
Improving the Characteristics of Bearing Surfaces
Supfina Grieshaber GmbH & Co. KG from Wolfach, Germany, presented an innovative finishing process for improving the antifrictional and bearing characteristics of surfaces. This process features not only rotational work piece movement and an oscillating tool movement in the axial direction, but also an oscillation of the tool in a radial direction. This creates not a full-coverage cross-hatched pattern, but a structured surface, featuring occasional recesses, in which oil can collect. This piezo-aided structural finishing offers an opportunity to replace the laser honing previously used.
Enhanced Metrological Efficiency
The topic of “Intelligence in Production” is also reflected in the new metrological solutions presented. Mitutoyo Deutschland GmbH company from Neuss, Germany, unveiled a compactly dimensioned 3D coordinate measuring machine called “Mach-3A 653,” which can be integrated as a station in concatenated lines. It detects incorrectly machined work pieces as rejects at an early stage. Corrective action can then be initiated. With their traversing speeds of 1,212mm/s, the machines are significantly superior to conventional coordinate measuring models, and are compactly dimensioned. The accuracy for length measurements is extremely tight, at 2.5µm.
Carl Zeiss Industrielle Messtechnik GmbH from Oberkochen, Germany, presented an X-ray-based process able to detect internal defects like blow-holes at the blank. With the aid of the associated software, the areas to be machined can already be digitally ablated, so that only the material quality in the relevant areas is taken into consideration.
Alicona Imaging GmbH from Graz, Austria, unveiled an optical microscope with which steep flanks of up to 80° can also be imaged. The systems featuring “Infinitive Focus” are based on a focus variation. With the associated software, the actual form shown can be compared to a set point contour. In addition, there is an option for measuring peak-to-valley heights or determining cutting-edge rounding phenomena.
Jenoptik Industrial Metrology Germany GmbH from Schwenningen, Germany, showcased a measuring unit for determining roundness and diameter of the bearings at crankshafts. The unit scores heavily not least in terms of its motorized adjustment, which takes the measuring head to its optimum position for measuring. This is particularly necessary when the grinding disk is so worn that a correction is required.
Etalon AG in Brunswick, Germany, premiered an innovative length measuring system for absolute measurements, in the shape of its Absolute Multiline Technology. The system is based on an adapted interferometric process, and can handle up to 100 independent measuring channels. Each channel has a range of up to 20m, with a measuring uncertainty of 0.5µm/m. Possible applications include monitoring production lines, monitoring or determining the geometrical shape of machines and of vibrations or thermal drift.
In times of shorter product life-cycles and higher variant diversity, the importance of CAD/CAM systems is growing. Automatic path generation on the basis of CAD drawings is meanwhile the state of the art for 5-axis milling. InterCAM-Deutschland GmbH from Bad Lippspringe, Germany, has transferred the dynamic path generation customary for milling to the turning operation as well. Under the term of “dynamic lathe,” the turning tool is effectively utilized by taking due account of the blade’s shape. In this way, the cutting values can be significantly improved and the tool’s useful lifetime increased by up to 300%.
“Intelligence in Production” also shows up in new developments for the field of CAD/CAM. Modern, operator-friendly user interfaces, for example, are featured in the new hyperCAD-S from Open Mind Technologies AG in Wessling, Germany. By incorporating ergonomic criteria, the wishes of CAM users can be responsively accommodated. The trend towards significantly user-friendlier interfaces is generally discernible among exhibitors in this field.
Expansion of Tool Management
Classical tool management, in which the tool manufacturer supplies a production line with tools, is the customary standard procedure. At EMO Hannover, the tool manufacturers are expanding their range of services by also designing the process involved. Because of shorter product life-cycles, the machining company often does not have the time to run its lines in or optimize them. Walter AG from Tübingen, Germany, will accordingly on request handle the entire process design work. The “Multiply” concept subsumes not only tool supply and inventory management, but also component-specific cost analyses. The process here is meticulously analyzed, and designed to ensure the lowest costs per good component.
Under the name of “Novo,” Kennametal Europe GmbH from Neuhausen, Switzerland, premiered a software package that helps the customer in autonomously designing his machining process. On the basis of a work piece drawing and the machine’s connection dimensions, the software recommends various tools that are required for the machining process concerned. Taking due additional account of the quality stipulations, moreover, cutting values are outputted. The data are based on empirical values, and grouped together in a “machining cloud.”
Enhanced Efficiency for Tools
In times of rising prices for hard metals, more effective use of hard-metal indexable inserts is essential. Numerous tool manufacturers unveiled solutions in which the inserts feature a higher number of blades. Iscar Germany GmbH from Ettlingen, Germany, presented five-blade inserts from its “PentaCut” product family for groove turning and thread turning. In this way, the hard-metal cutting material is efficaciously used. The “X4” system from Seco Tooling GmbH in Düsseldorf, Germany, has a four-blade insert. Though this tool possesses one blade fewer, thanks to the symmetrical configuration it can continue to be used without any problems if a blade breaks. Ingersoll Werkzeuge GmbH from Haiger, Germany, unveiled, under the designation of “Gold Max 8,” an eight-blade indexable insert for milling. The tool has been designed for milling cutters with tangential installation. The maximum cut depth is 8.7mm.
Another concept for even better utilization of a tool’s blades was premiered by ZCC Cutting Tools Europe GmbH from Düsseldorf, Germany, under the name of “Simply Coloured.” Here, the color of the insert’s borehole designates the application class. In addition, the individual blades are color-coded to indicate the cutting material concerned. In this way, the machine’s operator can easily recognize which cutting material is involved and which blade has already been in use. Prior to this, the blades on indexable inserts were often not used up completely, since it could not always be detected which blades had been in use.
A flexible production operation demands application-responsive clamping systems. One problem frequently encountered in this context is changeover of the devices concerned. Schunk GmbH & Co. KG Spann- und Greiftechnik from Lauffen/Neckar, Germany, presented a quick-change chuck for lathes. If a broad spectrum of different diameters has to be handled on a particular lathe, a complete replacement of the chuck is often necessary which can take up to one hour. The innovative chuck, which features a flex-cone, can be fitted in a matter of seconds. The concentricity lies at about 0.01mm. Under the name of “TOPlus mini,” Hainbuch GmbH from Marbach, Germany, presented a chuck for machining rotationally symmetrical components. Thanks to full-area clamping, the total clamping force required can be reduced. The manufacturer also offers the TOPlus variants with sensor technology that detects the clamping force in the process and adjusts it to suit the loadings encountered.
Conference on “New Production Technologies in the Aerospace Sector”
Under the aegis of the conference on “New production technologies in the aerospace sector,” perspectives and challenges in this specific sector were mapped out. MTU Aero Engines AG from Munich and Premium Aerotec GmbH from Varel, Germany, showcased aircraft requirements for the years ahead. There are several programs waiting approval for the engines, so that by 2020 an increase of 100 percent is predicted. The higher efficiencies demanded necessitate replacement of the materials used before. The use of titanium aluminides as a material for turbine blades is an important step forward in this context, one that entails major challenges in metal-cutting technology. In regard to the material mix, there is an ongoing shift towards carbon-fiber composites and titanium-based alloys. In the A350, more than 2,000 components are made of carbon-fiber composites (Duromer), more than 3,000 parts of carbon-fiber composites (Thermoplast) and more than 600 parts made of titanium. These materials likewise pose stringent requirements for the design of the metal cutting operation. In the case of titanium-based alloys, the choice of blade materials is usually restricted to hard-metal tools, resulting in low cutting values.
The tool manufacturer Kennametal Inc. from Latrobe, Pennsylvania reports good empirical results with CVD-coated diamond as a cutting material. In comparison to hard metals, the cutting speed has been increased from 65m/min to 300m/min. In the case of carbon-fiber composite materials, drilling operations are particularly difficult, since the drilling result is characterized by delamination and fraying. Mapal Präzisionswerkzeuge Dr. Kress KG from Aalen, Germany, unveiled tools designed specifically for these drilling operations: they focus on dry-machining when drilling composites made of CFCs and titanium.
Specialist Congress on “More Intelligence in Production”
Under the aegis of the specialist congress on “More Intelligence in Production,” the vision of “Industry 4.0” was addressed in detail. Besides the modern-day information technologies, new production technologies were addressed in general. Siemens AG from Munich emphasized in its presentation how a production line can be optimized by using a “Virtual Reality.” In the example, the output of a press line was increased by a simulation, and simultaneously its energy consumption cut by 40%. Robert Bosch GmbH from Stuttgart, Germany, primarily spotlighted its in-house production system. For implementing a pull principle, in particular, this system constitutes an important instrument. In its presentation, Audi AG from Ingolstadt, Germany, focused primarily on the issue of efficiency. A “Production Strategy 2020” has been drawn up, designed to upgrade the efficiency of its production operations. By 2018, for example, the energy requirement and the CO2 consumption are to be reduced by 25%. Successful measures are being communicated worldwide and implemented inside the company.
At EMO Hannover 2013, numerous solutions were presented in response to the to the latest social and commercial trends. Integrating modern-day information technologies into machine tools makes them more attractive and above all easier for the operator to control. In addition, revamped styling repeatedly emphasized how important a machine’s visual appearance has become as a sales argument. On the technological side, machines, tools and machine components have been developed that upgrade the productivity and efficiency of machining processes. Solutions were unveiled here in particular for growing sectors of industry like aviation or the energy sector, contributing towards cost-efficient manufacture of the requisite components.
For more information on EMO Hannover 2014, contact Bill Fox at 773.763.3461 or firstname.lastname@example.org.
Source: EMO Hannover