Breton automatic countersink solution for aerospace and automotive industry

Countersink? No problem!

The use of rivets is one of the most common standards for the permanent assembly of structural parts in aerospace and automotive sectors.
For reference only, the image on the right shows a typical distribution of different rivet types in a famous aircraft with a very recent design.
                                                              

Tratto da: http://www.france-metallurgie.com/2011/04/

Despite some minor limitations, this system offers useful advantages in the assembly process:

• Rivets are cheap
• The procedure is easy and fast
• They are available in many different types covering any need
• There is a long history and experience in their use leading to a good reliability guarantee 
• Compared to other permanent fixations, they can be disassembled quite easily with specific tools 
• They allow a calculated residual flexibility of the assembly 
• They allow easy and fast repair even on the field                   

tratto da: http://www.slideshare.net/hareeshang/riveted-joints-18171530

When rivets are used to assemble the external layers on the supporting structures, they need to fulfill another very important role because the resulting assembly is directly exposed to the airflow: the final surface must be as smooth as possible in order not to affect the aerodynamic performances.

This specific need is very common in the aeronautic and aerospace field and all designers solve it by selecting rivets with countersunk head.

It becomes therefore evident the need of an accurate hole on the surface prepared with a countersink: the rivet head needs to be hidden below or in line with the external surface profile.

Tratto da: https://www.aircraftcompare.com/helicopter-airplane/piaggio-p180-avanti-ii/356

Just to reinforce the importance of the final surface quality the rivet head flush requirement is directly expressed on the assembly  drawing  through specific symbols (like a welded joint) and described in detail through dedicated quality procedures involving, very often, also a source qualification need.

Tratto da: http://www.aslgroup.eu/en/fleet/12/piaggio-p180-avanti-ii

In order to better understand how important is to respect 

the perfect surface continuity we can consider that, on 

some aerodynamic very demanding design, the aircraft  performances are so sensitive that just the surface cleaning has a perceivable impact on the overall performances.

The standard way of performing the rivet assembly is manual with specific tools that allow improving the reliability of the process.

Tratto  da: http://www.northerntool.com/shop/tools/product_200451725_200451725

Generally, the structural parts and the sheet metal pieces are NC machined and prepared with smaller holes in order to guide the manual tools used to create the final hole and countersink prior to assemble the rivet.

Tratto da:  https://i.ytimg.com/vi/ykK37Ms2UiA/maxresdefault.jpg

Sometimes only one of the two element to be assembled is pre-drilled in order to allow compensation of assembly misalignments; in this case, operator’s job become even more complex and sensitive, thus requiring higher manual skills.

There are a few reasons for the aircraft manufacturer to choose this way rather than finishing the hole and the countersink on the NC machine:

• The hole and the countersink must be perfectly perpendicular to the surface
• The countersink depth need to respect quite a tight tolerance in order to avoid rivet head to be above the surface. We must consider that the material  thickness tolerance can be easily equal or even higher than the countersink one
• The position tolerance need to be very tight as well in order to guarantee that the two parts will match during the assembly
• Even if in a modern design all the parts are 3D modelled (it’s not the same in an older aircraft) the production processes of a structural part and a sheet metal one do not guarantee the same level of precision 
• The sheet metal is a flexible piece and it’s  very difficult to create a fixture that maintain the overall surface in the 3D model  theoretical position

All these reasons made the manual rivetting process the more convenient one, leaving to an expert operator the responsibility to recover all the previous processes misalignments.         

Tratto da: http://www.chinadaily.com.cn/bizchina/motoring/2014-09/17/content_18612888.htm

Everything said above is valid even if the sheet metal is classical aluminum or composite based. In this second case, some other points must be considered:

• The dust produced is very dangerous for the operator's health
• The material cut is very critical and need better control of the cutting  parameters
• The material surface control is even more complex

Until the business remains focused on small quantities and the market is ready to reward the “hand-made”, and the consequent high value added, as a “plus”, it’s possible to sustain the manual production process with respect to massive  production competitors.

How does all this match with NC 5 axis machining?

Tratto da: http://www.youtube.com/watch?v=Ih89unYl0-g

When the scenario changes to big numbers (typical of the civil market) with reduced prices and margins, the only solutionthe only solution to stay competitive is the process standardization   and automation, so the aerospace industry needs to find a partner who can help it achieving critical goals.                              

Tratto da: http://www.capmac-industry.it/en/aerospace/

On the market, it is possible to find solutions that substitute the operator job with a quite complex machine that request to introduce the full assembly jig into the machine in order to drill and rivet the components replicating the operator’s gestures.

Tratto da: https://www.youtube.com/watch?v=Ih89unYl0-g

This strategy is very expensive, requesting a huge space allocation and presenting many times issues due to aircraft structures accessibility limitations.

Breton is following a different way, allowing to save the huge amount of money necessary for the previous type of investment and keeping the maximum flexibility to apply the solution to any type of component.

Breton has developed specific machines and several solutions to support this type of challenge and has also a very strong and experienced process development team available to support customers before and after the integration of a fully comprehensive solution.

The only ground condition is the availability of a 3D part model, Breton takes care of anything else.

For each of the previous points supporting the benefits of a manual riveting process, Breton has a specific automatic solution leaving the final fastening to the operator but with the hole and countersink already prepared in the correct position, shape and  depth:

• Position precision is not an issue for any Breton equipment that is designed  to  achieve  the  best  5-axis  tolerance  on  the market.
• A specific automatic probing head is capable to calculate the real surface position in respect to that of the 3D model and calculate the corrections in order to recover depth of cut and surface perpendicularity
• The machine position is automatically modified without any operator assistance before drilling the hole and   countersink
• With this solution the fixture only needs to keep the piece well fixed but it can leave to the machine probing capability the real shape calculation
• The composite dust issue is solved avoiding the operator to be exposed to it during the material cutting
• The composite integrity is guaranteed using a special developed solution that avoids any contamination and completely removes any dust
• All the cutting parameters can be controlled much better than in a manual mode
• The software is also capable to monitor the surface stability during the cutting operation and can be programmed to react in different ways according  to  the material responsiveness.
• The structural part can be machined on the same trimming machine in order  to have the same level of precision. This way is the first step to guarantee a good assembly performance.

The core of Breton automatic countersink solution is the special probing head and compensating software.

They have both been designed at Breton’s and patented due to their specific and unique capabilities on the market.

The special probing head is stored in a specific holding device on the machine, protected and located outside the working area; when necessary, the machine automatically picks it up, while keeping  the tool change capability monitored through a specific application in order to avoid any collision with the device.

The system is composed of three mechanical transducers managed by a specifically developed NC control application in order to acquire the true position and orientation of the piece surface around the hole to be done.

The drilling program is a standard one where the machining cycle is substituted with the Breton routine to activate the countersinking head.

The typical drilling process follows these  steps:

• The machine collects the special probing device
• The machine picks up and measures the cutting tool (using a specific   Breton routine)
• The machine sets up the probing device on a reference gauge integrated in the machine (using a specific     Breton routine)
• The machine probes the surface in the theoretical position and orientation
• The real position and orientation is recalculated by Breton software
• Depending on the surface type and scratch sensibility, the machine position and orientation are corrected by either keeping the probes in contact with the piece or retracting the machine from it (average time of the full probing and position adjustment is 6 seconds)
• The drilling and countersinking cutter proceeds along the real hole axis until the probes detect the correct depth of cut (this time depends on the type of material, layer depth, type of cutter, etc..). The system is capable to respect a depth tolerance of +- 0.03 mm on a stable surface (or +- 0.06 mm if the surface is not perfectly supported and fixed by the fixture)

The machine head is also equipped with a special dust extraction hood in order to collect all the dust generated by the drilling process.

There is no limitation in spindle performances as all the probing systems are static and connected to the head flange without any external   wire.

Depending on the material type, the head can supply compressed air, spray oil mist or pressurized coolant up to 40 Bar as the probing devices are fully sealed.

The following pictures explain the capability of the special head comparing the results of countersinking with and without the Breton solution:

This sequence is useful to understand better how the full process is working:

The system can be installed on any Breton machine giving the customer huge advantages compared to the manual process, spending just a small portion of the investment requested by more sophisticated solutions. 

(Breton is not yet assembling the rivets…).

Summarizing the points of strength of Breton solution:

• One machine to trim, drill and countersinking
• Precise process control
• Small investments in a machine accessory

Since one of Breton’s major points of strength is its capability to hear the customer’s requirements, we are working to further improve this system reviewing the design and testing a contactless   solution.

Test Case: Composite panel

Machine type: Eagle 1500 2T K80 

(5 axis overhead  gantry machine) 

Machine size:  

X=8000 mm

Y=4000 mm

Z=1500 mm

Machine accuracy:  

X=+-0.02 mm 

Y= mm

Z= mm

Number of countersinks on each side of the part: 55

Countersink depth: 0,31 ± 0,08 mm 

Process stability achieved: Cp 1,34

Cpk (lower) 1,14

The following graph shows how the system recovers the hole surface perpendicularity starting from the theoretical one, measuring the real surface orientation (red lines in the graph), correcting the head A and C axis and checking the final result (green lines in the graph).

After this first phase, the system starts monitoring the countersink depth comparing the probes data with the target   values.

The final result, achieved on a composite part not perfectly stable on the fixture, is shown in the process control chart here   below:

Consideration:

The process stability is very nice giving a big safety margin. The customer chose to further increase the safety margin moving the average countersink depth in the lower tolerance direction (as show by the Cpk value).

For more information please write to mail@breton.it.

Thank you for the attention and best regards.

Bye-bye

Sergio Prior

Read More

aerospace industry, automotive industry, Breton automatic countersink solution, structural parts aerospace sector

Innovation and quality for aerospace applications by Breton

Aerospace, the industry continuously searching for innovative materials offering better performance and always looking for micrometrical accuracies.

Piaggio Aero Avanti Evo



An  industry that needs someone who can promptly develop cutting edge production solutions which could be both competitive and immediately reliable.

That's why many major Aerospace players selected Breton as a partner, the Italian company manufacturing high-speed machining centres: continuous research and innovation are in its DNA.

From the most affordable machine configurations up to the large and complex automated manufacturing systems, Breton is always focused in providing its customers with the best ‘Return Of Investment’ solutions.



Click on the image for a virtual tour inside Breton



At their engineering and manufacturing headquarter in Northern Italy as well as in the other 6 service centers worldwide, a dedicated staff of experts is performing preventive part and process analysis in order to determine the most effective and efficient way of producing aerospace parts using a very wide mix of technologies including turning, milling, grinding or in-process probing.

Breton competences are ranging from the lightest composite materials up to the toughest special alloys and,doesn’t really matter if the application is around an aero-engine part or a large structure, their vertical gantries provide an answer even to the most specific demands.

HIGH DYNAMICS

There are multiple advantages offered by the architecture of the Breton machines (vertical trunnion tables, large overhead gantries and moving portals) such as reduced footprint, greater  and comfortable accessibility, very high dynamics, thermo-symmetry and thermal stability combined to a user-friendly programming and a low maintenance requirement.

These benefits become even more evident when a single machine is capable of performing more than one task simultaneously in a perfect multitasking approach, a concept in which Breton is well-experienced.

As an example, in its ceaseless research for innovation, Breton has recently introduced two revolutionary technologies that open up new horizons for the machining of aero-applications.

COUNTERSINKING

The heart of one of these is a machining head that can drill and countersink not only faster but also more precisely than ever before. It can be installed on a variety of 5-axis machining centres, such as those of the Breton Matrix and Breton Eagle families.

No special programing is required since automatically 3 accurate probes around the cutting tool come into contact with the surface of the workpiece to detect the real position in the space, directly adjusting the perpendicular direction to the surface and measuring the exact countersinking depth.

All in one shot. It's a unique solution, which has already been adopted by various aerostructure manufacturers who now supply components with a higher degree of accuracy in much faster lead times.

ULTRASONIC CUTTING

Another exciting innovation focuses on the accessories Breton has developed for ultrasonic cutting, ideal for machining core materials with aramid and aluminum honeycomb, for structural components which must be lighter than ever while maintaining their structural rigidity, produced at incredible speed.

Both technologies are automatically managed and are interchangeable with other conventional rotary cutting tools, performing a series of operations with just one machine thus reducing investments, production costs and times, while guaranteeing greater accuracy and more efficient productivity.

INCREASE PRODUCTIVITY

Considering the important existing order backlog in several aerospace programs, the rump-up stage of many others and the extremely positive outlook for the future of the air transportation, there is no doubt that most of the international aerospace players need to increase productivity and be prepared for incoming growing demand.

In such a context  the selection of a reliable and dependable machine tool partner is becoming more and more important every day. If you need a robust supplier granting stability and innovation for the years ahead, Breton is the one.

BRETON MACHINE TOOLS DEPARTMENT

For more information write to mail@breton.it.

Read More

5 axis milling, 5-axis machining centres, aero-engine part, aerospace industry, aerospace parts, breton, Breton machines, high-dynamics, turning

NEW Matrix JET

A competitive solution

High-speed precision machining centre for milling complex three-dimensional work-pieces which require accurate machining and continuous axis interpolation. MATRIX JET 1000 is the ideal solution to satisfy production requirements across a multitude of industrial applications from aerospace industry to automotive, die-manufacturing and design.     

Wide choice of configurations for customized performances

Various solutions for the best machine configuration to satisfy each need:

· Standard model with one working area

· Model with two working areas for pendular machining

Easy access and perfect visibility

Great accessibility and visibility of the working area thanks to the machine structure with moving bridge and wide lateral doors that make the work-piece loading easier.

Precision, Dynamics and Flexibility when machining at high speed with 5 continuous axes

In order to guarantee high performance, the new MATRIX JET 1000 is built on a heavy-duty cast iron bedplate which acts as a support for the bridge sliding. Columns consist of a sandwich structure made of arc-welded and stabilized steel.

Monitoring and in-process inspections

MATRIX JET 1000 can be supplied with a laser tool presetter and a radio frequency probe for acquiring work-piece size and coordinates.

A superior head

The electrospindles offer always the best machining performance thanks to the cast-iron fork designed head which offers structural rigidity with efficient vibration damping properties. The highest-performance models are provided with Direct Drive motorized heads.

High-speed, Performance and Precision

The carriage and beam travel on properly dimensioned recirculating roller guideways ensure machining precision and stability. Axes are moved by a ground ball screw and double preloaded ball nut assembly. Maximum axis precision is achieved thanks to the micrometric technology applied. Axes are powered by digital drives and ultimate generation brushless servomotors.

Wide choice of electrospindles

The MATRIX JET 1000 machining centre can be supplied with a wide range of electrospindles depending on the type of material to be machined. Machining precision is always guaranteed by the thermal stabilising system which consists of a special software designed and developed to compensate natural thermal expansion in the electrospindles when machining conditions vary.

The ideal cooling system

Depending on the type of machining, the tool cooling system can use a coolant liquid which flows inside and outside the spindle (60 L/min) with fixed or variable (up to 70 bar) internal pressure, or incorporate a spray mist system, or simply use compressed air.

For INFO and request write to mail@breton.it.
By-by
Sergio Prior

Read More

aerospace industry, automotive, breton vertical machining centres, matrix jet, pendular machining