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Based in Chennai, Proteck was established over twenty five years ago and is now one of India's leading production machinery suppliers; distributing, supplying and manufacturing a wide range of printing machinery, machine tools, metal cutting & forming equipment and CAD/CAM software throughout its home market and in more than 20 countries world-wide. Its manufacturing subsidiary, Proteck Precision has a young, dynamic and highly qualified engineering work-force that develops and produces exciting new economy solutions for the fast growing Indian manufacturing industries as well as providing competitively priced machinery that is exported beyond Asia. The technology driven company has styled its production, quality control and engineering logistics departments on a European model and has two very modern manufacturing facilities in Chennai complete with state-of-theart CAD/CAM, MRP systems and the latest ISO accreditations. Proteck began working closely with Kollmorgen EU following an impressive performance and reliability experience of the global motion systems suppliers' servo motors and drives included as part of German CNC machine tools that Proteck were distributing into its own markets.
The learning curve and close relationship progressed with product training and close application support from Kollmorgen European based production and development facilities and further support from its Mumbai based team.
Proteck Engineers have had extensive training at Kollmorgen's Ratingen facility. Today, as Proteck develops its own special purpose laser cutting and CNC machine tool range, Kollmorgen is very firmly established as a manufacturing partner.
"Our latest generation laser profiling and machine tools have developed from our more than two-decade experience in supplying and supporting machine tool technologies from our partners, as well as from our increasing in-house design and manufacturing capability," says Mr. K. Bala, Proteck's Managing Director, "For both of these important factors, we can count Kollmorgen as a major technology contributor and a valued partner."
Proteck's evolution to manufacturing its own machines began with high specification CO2 equipped 3-axis laser cutting machines with flying optics that cater to a wide range of flat sheet material. These small footprint machines originally included cast-iron beds and single lower axis geometry that allowed open three-side access for flat sheet sizes around 2.5 x 1.5 metres. Bosch Rexroth or Siemens CNC controller options fully integrated with Proteck's highly developed MetaCAM CAD/CAM software allows ease of use for all types of sheet metal cutting. As a development from this machine Proteck introduced a "Plug and Play" model for job and fabrication shops that included all of the features of the previous machines but used a much lighter and lower cost welded frame construction. The technology leader had begun its ground-breaking marketing concept that a laser cutting machine should be no more complicated than an office laser printer.
As part of this continued initiative, its designers looked hard at the transmission mechanics. Precision ground ballscrew cost for a 2.5 m travel range is expensive and the single-axis/single-screw design with its overhung load requires more sturdy and costly linear motion guide bearings for adequate support. Furthermore, to maintain a good dynamic performance, the ballscrews need to be large in diameter to allow high rotation speeds, which increases servo motor and servo drive size.
With the need to produce even longer travel machines that could provide larger flat sheet work, Proteck and Kollmorgen EU began to address some central questions:
• How to maintain the +/-10µm bi-directional repeatability performance and up to 110 m/min max linear speed, required of the machines?
• How to reduce the power requirements and provide increased efficiency?
• How to further drive down powertrain component costs?
The result was the introduction of an innovative rack and pinion drive system for the long-travel lower axis of the machine for a new 3-axis bridge laser machining centre which includes two synchronised lower X-axes supporting a gantry Y-axis, and a vertical Z-axis.
The initial conception looked at linear motor technology for the long-travel dual synchronised X axis but the cost for this was prohibitive for the market sector Proteck targeted for the machine. Proteck's cost effective rack and pinion design concept was thus developed with the awareness that backlash and repeatability performance would need to be achieved using a novel approach. The special preload mechanism was realised by mounting the pinion and its motor on an eccentric pilot circle and a gear tooth geometry that allowed full face gear contact and in-situ adjustment to minimise lost motion and hysteresis. This performed more than adequately at the point of the actual rack and pinion face, but when combined with a standard rotary servo motor which required a planetary gearbox to develop the torque required to drive the load, the gearbox backlash, albeit relatively small, proved prohibitive. The answer was to design the pinion-to-rack transmission around the Kollmorgen KBM series direct drive motor.
The KBM's separate rotor and stator packages are now supplied in kit form and directly mounted on the machine by Proteck within their own bearing system and protective cover, with power and encoder connectors built-in. The mounting arrangement directly couples the large diameter pinion shaft to the rotor as a single solid assembly, restricting lost motion and potential unwanted harmonics that a flexible coupling may give rise to. The resulting design has been field proven for extremely low backlash and has a dynamic and throughput specification which is very close to linear servo motor performance. The rack and pinion system is also very resilient to debris and does not require the degree of protection that a linear motor system would necessitate for a laser machining environment.
Simply put, the Proteck rack and pinion system, combined with the Kollmorgen direct drive KBM motors has less parts, is more energyefficient and delivers higher speed and accuracy, reducing the backlash and lost motion to well below the desired specification.As an intrinsic part of the design, Kollmorgen S700 servo drives with their multifeedback capability are used with both resolver feedback, mounted on the KBM motor for commutation, and magnetic linear scales for the position loop. The feedback protocol is SSI absolute, EnDAT or alternatively BiSS to suit a choice of CNC controllers with set-up and monitoring via EtherCAT which is integrated in all S700 drives. Many optional features of the advanced servo drive may be included in the machine specification. These include STO (Safe Torque Off) for SIL 2 and 3 safety standards, and Ethernet connectivity for set-up and monitoring. EtherCAT is also available and will be integrated in future machines for axis synchronisation.
With a maximum sheet size of 3.1 x 1.6 m, the new generation flat sheet cutting machines also use Kollmorgen AKM series rotary servo motors withµm series planetary gearheads for the Y axis as well as the Z axis with a brake fitted. For complete compatibility, S700 drives are used throughout the machine. This machine will also benefit in the future from a cost-optimized CNC from the German cutting machine specialist Eckelmann, who also works closely with Kollmorgen EU. Developing on from the flat bed, 3-axis bridge gantry machines Proteck's latest laser cutting machine, the Sl 2530, is a massive 7-axis "walkin" machining centre which includes an advanced flying optics head design that provides laser cutting of vertical and angled sides of formed workpieces. Large three-dimensional fabricated sheet metal workpieces are fixed to a stationary central table and the multi-rotational laser head is guided to always maintain the optimum perpendicular angle for perfect cutting. KBM direct drive motors with Proteck's innovative rack and pinion mechanism are used for main horizontal axes of the machine which cover an area of 1.6 x 3.3 x 0.7 m.
Furthermore, the hollow shaft KBM motor is also used as the main drive for the multi-rotational flying optics system, allowing feed-through of the laser delivery and focussing system whilst maintaining the flexibility and precision to provide completely synchronised twin rotary axes featuring nX360 degrees and +/-135 degrees rotational strokes. The machine also uses a complement of AKM servo motors on other axes along with matching S700 drives, allowing Proteck and its customers to reduce spares and inventory costs. With the success in performance and reliability that Proteck has experienced with the KBM and AKM motors, other developments have followed.
The BMT 125 is an advanced Siemens CNC controlled table-type horizontal boring and milling machine, which has recently benefited from the replacement of standard rotary servo motor drives and backlash-prone gearboxes with KBM direct drive motors. Directly coupled to X, Y and Z axis ballscrews, the improved transmission system has less parts, more efficiency, uses less energy and enables higher speed and accuracy by removing the backlash induced by the gearbox. Once again, Proteck install the rotor and stator components into its own bearing design, complete with a protective housing that takes care of the electrical connections.
In conclusion, the fast moving growth in the BRIC economies is driving the well-placed Proteck to continued success, and more machines that will include the benefits of direct-drive technology from Kollmorgen. Development time is also being reduced. "With fewer parts to design into our machines and the standardisation of Kollmorgen's field-proven direct-drive technology, we have reduced our engineering time," says Mr. K. Bala. "In this way we can take products to market more quickly — and with fewer components, improved precision, better machine reliability and higher efficiency, we can steal the march on our competitors and gain more market share."
Related Glossary Terms
- backlash
backlash
Reaction in dynamic motion systems where potential energy that was created while the object was in motion is released when the object stops. Release of this potential energy or inertia causes the device to quickly snap backward relative to the last direction of motion. Backlash can cause a system’s final resting position to be different from what was intended and from where the control system intended to stop the device.
- boring
boring
Enlarging a hole that already has been drilled or cored. Generally, it is an operation of truing the previously drilled hole with a single-point, lathe-type tool. Boring is essentially internal turning, in that usually a single-point cutting tool forms the internal shape. Some tools are available with two cutting edges to balance cutting forces.
- computer numerical control ( CNC)
computer numerical control ( CNC)
Microprocessor-based controller dedicated to a machine tool that permits the creation or modification of parts. Programmed numerical control activates the machine’s servos and spindle drives and controls the various machining operations. See DNC, direct numerical control; NC, numerical control.
- flat ( screw flat)
flat ( screw flat)
Flat surface machined into the shank of a cutting tool for enhanced holding of the tool.
- gang cutting ( milling)
gang cutting ( milling)
Machining with several cutters mounted on a single arbor, generally for simultaneous cutting.
- laser machining
laser machining
Intensified, pulsed beams of light generated by lasers—typically carbon dioxide or neodium-doped yttrium aluminum garnet (Nd:YAG)—that drill, weld, engrave, mark, slit and caseharden. Usually under CNC, often at both high cutting rates (100 linear in./sec.) and high power (5kW or more). Lasers also are used in conjunction with in-process quality-control monitoring systems allowing measuring accuracies of 0.00001".
- linear motor
linear motor
Functionally the same as a rotary motor in a machine tool, a linear motor can be thought of as a standard permanent-magnet, rotary-style motor slit axially to the center and then peeled back and laid flat. The major advantage of using a linear motor to drive the axis motion is that it eliminates the inefficiency and mechanical variance caused by the ballscrew assembly system used in most CNC machines.
- milling
milling
Machining operation in which metal or other material is removed by applying power to a rotating cutter. In vertical milling, the cutting tool is mounted vertically on the spindle. In horizontal milling, the cutting tool is mounted horizontally, either directly on the spindle or on an arbor. Horizontal milling is further broken down into conventional milling, where the cutter rotates opposite the direction of feed, or “up” into the workpiece; and climb milling, where the cutter rotates in the direction of feed, or “down” into the workpiece. Milling operations include plane or surface milling, endmilling, facemilling, angle milling, form milling and profiling.
- milling machine ( mill)
milling machine ( mill)
Runs endmills and arbor-mounted milling cutters. Features include a head with a spindle that drives the cutters; a column, knee and table that provide motion in the three Cartesian axes; and a base that supports the components and houses the cutting-fluid pump and reservoir. The work is mounted on the table and fed into the rotating cutter or endmill to accomplish the milling steps; vertical milling machines also feed endmills into the work by means of a spindle-mounted quill. Models range from small manual machines to big bed-type and duplex mills. All take one of three basic forms: vertical, horizontal or convertible horizontal/vertical. Vertical machines may be knee-type (the table is mounted on a knee that can be elevated) or bed-type (the table is securely supported and only moves horizontally). In general, horizontal machines are bigger and more powerful, while vertical machines are lighter but more versatile and easier to set up and operate.
- profiling
profiling
Machining vertical edges of workpieces having irregular contours; normally performed with an endmill in a vertical spindle on a milling machine or with a profiler, following a pattern. See mill, milling machine.
- quality assurance ( quality control)
quality assurance ( quality control)
Terms denoting a formal program for monitoring product quality. The denotations are the same, but QC typically connotes a more traditional postmachining inspection system, while QA implies a more comprehensive approach, with emphasis on “total quality,” broad quality principles, statistical process control and other statistical methods.