Burnishing

Type of technology

Forming processes

Development phase

advanced

Level of innovation

national level

Scale of production

batch, mass

Technology readiness level TRL

Description of the technology

Burnishing is a non-subtractive manufacturing process in which pressure is applied to the surface of a workpiece by burnishing tools in the form of rollers, balls, etc. The strengthening or hardening of the surface layer of the workpiece is achieved by the mechanical changes caused by the burnishing process.

During burnishing, the surface layer of the workpiece is plasticised. At the point of contact, the burnishing force induces contact stresses in the surface layer of the material. When the value of these stresses exceeds the yield point, the material near the surface begins to flow. The elastically deformed part of the surface layer then interacts with the plastically deformed part of the layer, causing compression and displacement.

With regard to the nature of the action of the burnishing tools on the surface, the burnishing process is divided into:

static – the burnishing forces are invariable and act on the workpiece through the burnishing tools, which are in continuous contact with the workpiece. Static burnishing techniques include:

sliding burnishing – a smooth burnishing tool (usually a diamond) is pressed against the surface of the workpiece with an appropriate force and moves along its surface, causing sliding friction and plastic deformation of surface irregularities in the burnishing zone.
rolling burnishing – during the process, the burnishing tools (discs, balls, rollers) roll along the workpiece surface under the load of statically acting thrust forces.

dynamic – the burnishing forces change periodically and the burnishing tools are not in continuous contact with the workpiece. Among the dynamic burnishing techniques, the following can be distinguished:

concentrated impact burnishing – this process involves the cyclical concentrated impact of rotating burnishing tools in the form of balls (also discs or mandrels) on the surface of the workpiece.
dispersed impact burnishing – this process involves the impact on the surface of the workpiece with a stream of balls moving at high speed, delivered by a rotor ejector or compressed air.

Purpose of use

high-precision finishing of surfaces of any geometry

Use in industry

all industries, mainly engineering, automotive and aerospace industries

Alternative technologies

micromachining
lapping
superfinish
honing
electrochemical machining (ECM)

Visualisation of action

Advantages

the possibility of obtaining a surface with very low roughness and large radii of rounded vertices and notches (larger than after grinding)
large material share of the roughness profile (about 90%)
high load capacity of the surface that guarantees considerable durability of fits and connections (e.g. injection molding)
no hard tool splatter (abrasive grains; build-up particles) and chips on the surface subjected to burnishing
good adhesion and uniformity of electroplated hard coatings
increased hardness by generating permanent internal compressive stresses in the surface layer of the crush
increased resistance to wear
e.g. abrasion; form and surface fatigue; surface corrosion
low coefficient of friction and good adhesion of lubricants to the surfaces treated with burnishing
high worker safety during operation (low temperature and total absence of chips; harmful dust or sparks)

Disadvantages

low dimensional-shape accuracy (especially elastic-pressure burnishing; which does not generally improve accuracy after pretreatment)
limitation of the hardness of the workpiece material (in the case of rolling burnishing with steel elements practically to about 45 HRC)
the possibility of the occurrence of flaking of the burnished surface when applying high pressure forces during the machining process
the need for careful (no burrs and overgrowth) and accurate processing prior to crushing due to the possibility of the occurrence of zones of uneven crushing
the occurrence of technological errors in the axial section of the workpiece (e.g. crushing of the zones of insertion and removal of the burnisher from the hole as well as material corrugations and edge deformations)
noisiness of operation of most tools for dynamic burnishing

Workpiece material types

steel
non-ferrous metals
non-ferrous metals alloys

Examples of products

turbine blades

Implementation of the technology

Required resources

burnishing tools
tooling
dynamic burnishing station (e.g. rotor or pneumatic ejector)

Required competences

training in finishing techniques
training in machining techniques

Environmental aspects

Water consumption

Energy consumption

Waste generated

Expert evaluation

Competitiveness

Usability

Environmental impact

Development centers

Opole University of Technology
Poznan University of Technology
West Pomeranian University of Technology in Szczecin

Legal conditions

none