Lotus Cars Ltd. launches its most accurate sports car ever

November 15, 2022 - 06:00am
The Lotus Emira

Since the first Lotus car was built in 1948, the British automotive company headquartered in Norfolk, England, has been a beacon in the automotive industry for the design and manufacture of high-performance cars born out of legendary success on the racetrack.

The latest sports car, the Emira, is by far the most accurate model ever built by Lotus thanks to an upgrade in quality control (QC) at the company's sports cars factory in Hethel, Norfolk, UK. It includes investment in a 5-axis HC-90TR twin-arm coordinate measuring machine (CMM) manufactured in Castle Donington by LK Metrology.

A Lotus Emira being delivered by an automated guided vehicle from the production line to    the LK CMM to undergo stage 1 inspection.
Top: The Lotus Emira. Above: A Lotus Emira being delivered by an automated guided vehicle from the production line to the LK CMM to undergo stage 1 inspection.

The automated, multi-sensor inspection cell, part of multi-million dollar investments made by Lotus since 2017, delivers absolute, 100 percent, non-contact dimensional inspection at production-line speed, enabling real-time quality control.

The CMM installed in Hethel is set one meter into the floor on a special foundation. It means that a car for the inspection carried on an automated guided vehicle (AGV) can access the area without the need for any lifting equipment.

Advanced, triple-laser cross scanners are deployed on both arms to measure features automatically on both sides of the Lotus Emira simultaneously. Notably, the LK HC-90 is the world's most accurate range of horizontal-arm CMMs, able to measure to a volumetric accuracy of 10.0 μm + L/200 and with 6 μm repeatability. The machine combines the high performance of a bridge-type CMM with the flexibility of the horizontal-arm configuration widely used in car plants.

The Emira chassis, which remains on the AGV, is lowered into position and aligned ready for inspection by laser scanning.
The Emira chassis, which remains on the AGV, is lowered into position and aligned ready for inspection by laser scanning.

The CMM completes automated measuring cycles so quickly that it can keep up with the quick TAKT time that defines the speed of the Emira production line. The fast throughput enables every car to be inspected, making this Lotus model the first whose manufacture is supported by such comprehensive QC.

On two occasions, at different stages of the car's build, the LK HC-90TR captured a total of 130 measurements in scanning routines that took about 12 minutes and 8 minutes respectively. The rapid inspection cycles leave plenty of time for an AGV that has delivered a chassis to the CMM to load it and subsequently return it to the line.

Before metrology starts, there is also time to verify the car's alignment relative to the carline reference point system in the CMM, as well as to calibrate the laser scanners using dedicated calibration spheres. For speed and accuracy, they are touch-probed using sensors that are exchanged automatically by the arms from a rack. The same sensor is used for probing some critical internal dimensions of the car, while the laser scanner performs high-speed scanning of the freeform surface areas.

Tom Mackrill, dimensional quality manager, Lotus Cars.
Tom Mackrill, dimensional quality manager, Lotus Cars.

Compared to traditional QC practices underpinning the manufacture of these largely hand-built sports cars, which are made from high-tech, lightweight composite panels, the benefits of rapid point cloud acquisition and digitization in the LK cell are enormous.

Formerly, a sample chassis would have undergone measurement line-side on a manual CMM having an arm equipped with a touch probe. Fewer features would have been checked in up to five hours on typically one in every couple of dozen chassis, which had to be taken out of production and reinserted afterward.

There was potential for error not only through human intervention but also due to a need to reposition the car during inspection to compensate for the limited axis travels of the old CMM. More seriously, any of the unchecked cars between the samples might be out of tolerance, leading to time-consuming, expensive rework further down the line.

Tom Mackrill, dimensional quality manager at the factory said, "The Lotus Emira is our last new car to have an internal combustion engine, as we are going all-electric in [the] future. We are aiming the product at the premium segment of the global market, so a very stable production process is required to ensure high build quality.

"Production rate of this car model in 2022 is substantially higher than last year, when we were ending production of the Elise, Exige and Evora [models], and is increasing strongly. So we need a QC solution that not only supports high precision but is also fast enough to generate large amounts of data quickly to match the production rate.

Close-up of the Renishaw PHS-2 wrist (left) that allows infinite positioning of the Nikon XC65DX-LS cross scanner, ensuring that the required inspection data is acquired well within the TAKT time of the Emira production line.
Close-up of the Renishaw PHS-2 wrist (left) that allows infinite positioning of the Nikon XC65DX-LS cross scanner, ensuring that the required inspection data is acquired within the TAKT time of the Emira production line.

Mackrill said that other inspection technologies including those involving various robot-mounted measuring heads were researched. He said that the team concluded that robots, particularly if they are mobile, would introduce extra potential error in addition to that of the measuring devices they carry and would need a reference measuring system to calibrate and realign them. 

"We, therefore, concluded that a static CMM was the way to go in the production process of our new car, with a twin-arm configuration and laser cross scanners providing the required speed of metrology," said Mackrill.

He added that the reliability and repeatability are driving the dimensional quality of the Emira by feeding back data to the production line to validate and control the process, ensuring each vehicle is built right, the first time. Such feedback is particularly important to the composite panel framing facility due to the potential for variability in the adhesive bonds.

Laser scanners' infinite positioning
The Renishaw PHS-2 two-axis CNC wrists that carry the laser scanners can rotate continuously and have infinite positioning, unlike conventional probe heads that only adjust in 7.5-degree steps.

Each scanner can therefore be precisely angled throughout an inspection cycle, allowing optimal positioning both inside and outside the chassis for rapid acquisition of freeform and geometrical data.

When inside the vehicle, the PHS-2 can rotate under program control to look outwards at the interior of the bodywork to take measurements. The DMIS programs controlling each arm are essentially mirror images, with additional movements inserted separately to address the minor differences unique to each side of the car.

The Nikon XC65DX-LS cross scanner with three laser lines captures in a single orientation and scan pass three times the amount of data that can be acquired by a single-line laser scanner.

It enables short inspection cycles on the LK HC-90TR to support 100 percent QC of the Emira. The built-in technology means that the sensor is unaffected by the color or reflectivity of what is being measured. It also provides automatic, real-time adjustment of the settings not only between successive laser stripes, but also for individual points along each line. The LS variant of the scanner signifies that it has a longer stand-off distance, up to 170 mm, allowing it to access difficult-to-reach features.

Two-stage inspection
AGVs deliver every Emira to the CMM from the production line, both early on from the end of the framing line (stage 1) and when the car is fully assembled (stage 2).

It is deposited without manual intervention in the carline and a bar code reader, known as a scripting system, verify the vehicle's identification number, color, whether it is right or left-hand drive and if a stage 1 or stage 2 metrology program should be run. The car in its stage 1 condition is not conventional body-in-white, as the body panels are already painted and the steering column and wiring looms are in place.

After automatic calibration of the laser scanners, they take 130 measurements around the car over the two stages to assess the accuracy of the vehicle. Suspension and engine mounting points are critical areas for inspection. Control of gap-and-flush is especially important, as the spacing between panels impacts directly on the perceived quality of the car on the forecourt. 

Programs are created largely automatically from CAD models of the Emira in LK CAMIO software. It ensures the laser scanners move along paths such that the surfaces being measured are always within their field of view.

The low-noise point clouds captured are filtered to produce smooth, highly detailed meshes that can be aligned to enable comparison of the measured data with the CAD model. Inspection tools are included for intelligent feature extraction, GD&T tolerancing and profile analysis, backed by rapid feedback of results to the production line and comprehensive reporting.

Lotus Cars elected to implement this two-stage, offline, in-process metrology solution as it is most expedient for the company's needs.

However, in other scenarios one HC-90TR or more could be positioned within the production flow line itself, checking dimensions before the vehicle passes to the next build operation. Other offline applications include quality audits and verification checks.

Turnkey automated solution
The metrology cell was installed and commissioned by LK in the Hethel plant in January 2021, ahead of the start of Emira production.

The automated equipment has been instrumental in raising production efficiency and lowering the labor cost content of the cars by ensuring that dimensional inspection controls the manufacturing process, rather than merely qualifying the compliance of the measured data. It is driving the production strategy for the continuous improvement of individual parts and the whole process with the goal of zero-defect manufacture, which is the purpose of Industry 4.0 with which the LK hardware and software are compatible.

"Lotus had not dealt with LK before but I had previous experience of the CMM brand during employment in another car plant," said Mackrill. "Once we had decided that the gold standard of static coordinate measurement was the correct metrology route for us to take, we reviewed several offerings from different potential suppliers. 

"LK stood out as being the best in terms of high-end technology. The ceramic construction of the machine provides excellent stability combined with light weight for accuracy and speed. LK supplied a fully configured, multi-sensor, turnkey solution complete with first-draft measuring programs and ancillaries. Only the fixtures supporting the car body were provided by us." 

To underline the faith that Lotus Cars has in LK, the vehicle manufacturer has also invested recently in four further CMMs, all smaller bridge-type machines, for its nearby LAS (Lotus Advanced Structures) division.

Used for QC of chassis components, there are three LK Altera M machines with measuring envelopes of nominally 3 x 2 x 1.5 m, 2 x 1.5 x 1.2 m, and 1.5 x 1.0 x 0.8 m respectively and a larger, higher accuracy ULTIMA CMM with a 4 x 2 x 2 m inspection volume.

Related Glossary Terms

  • calibration


    Checking measuring instruments and devices against a master set to ensure that, over time, they have remained dimensionally stable and nominally accurate.

  • 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.

  • computer-aided design ( CAD)

    computer-aided design ( CAD)

    Product-design functions performed with the help of computers and special software.

  • metrology


    Science of measurement; the principles on which precision machining, quality control and inspection are based. See precision machining, measurement.

  • 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.

  • tolerance


    Minimum and maximum amount a workpiece dimension is allowed to vary from a set standard and still be acceptable.


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