A D V A N C E D M A T E R I A L S & P R O C E S S E S | O C T O B E R 2 0 1 5

6 2

22

TECHNICAL SPOTLIGHT

ULTRAFAST BORIDING: A TRANSFORMATIONAL TECHNOLOGY

A

n ultrafast, efficient industrial-scale boriding process

can drastically reduce costs, increase productivity,

and improve the performance and reliability of a va-

riety of machine parts. Component surfaces are converted

into thick, hard boride layers in minutes, which dramatically

increases resistance to degradation due to wear, abrasion,

erosion, scuffing, and corrosion. By comparison, achieving

such layer thicknesses using traditional pack boriding re-

quires several hours, and surface hardness levels and other

properties are lower than those produced using the newpro-

cess.

The novel, environmentally friendly technology, devel-

oped at Argonne National Laboratory, Ill., enables treating

thousands of industrial components in one batch, without

creating solid or liquid waste and gaseous emissions. The

key ingredient used during boriding is a natural boraxminer-

al, which is safe to handle. Researchers say the new process

is a transformational technology that can complementmany

current surface treatment processes, such as conventional

boriding, carburizing, nitriding, carbonitriding, and physical

and chemical vapor deposition (PVD and CVD).

PROCESS DEVELOPMENT

The ultrafast, large-scale boriding process is the result

of a collaborative effort involving Argonne (lead partner),

Bodycote, and Istanbul Technical University, stemming from

a project fundedby theU.S. Department of Energy-Advanced

Manufacturing Office. The initial part of the project involved

scale-up of a small proof-of-concept unit (1.75-in. diameter

unit with 250-g electrolyte capacity) to 4- and 6-in. diameter

intermediate units, and then to a pilot-scale unit with a 22-

in. diameter crucible size featuring a capacity of 130 kg of

electrolyte. This led to building a production-scale unit with

a melt capacity of 4000 kg. The evolution of the large-scale

boriding technology from inception to large-scale imple-

mentation is shown in Fig. 1.

The ultrafast method uses a battery-like design, where

each electrochemical cell contains a positively charged cath-

ode, negatively charged anode, and molten borax-based

electrolyte. Bath temperature is roughly 1400°F. Parts are

attached to the cathode, and when the unit is connected to

a power source, ions flow from the anode to the cathode,

depositing boron on the cathode and attached workpieces.

Boron subsequently diffuses into the metal and reacts to

convert near-surface regions intometal borides. The process

is completed in minutes, producing a denser, more uniform

coating, and requires 85% less energy than conventional bo-

riding. Traditional pack-boriding, by comparison, involves

baking parts in a complex mixture of powders at a tempera-

ture around 1800°F, often for 10 hours or longer.

Ferrous and nonferrousmetals and alloys (e.g., titanium,

tantalum, zirconium, tungsten, niobium, molybdenum, most

nickel- and cobalt-base superalloys, and cobalt-chrome al-

loys), intermetallics, cemented carbides, and cermets (which

are not possible to treat using conventional boriding meth-

ods) can be treated with the new process. Surface hardness is

increasedby factorsof 3 to10 (i.e., 15 to45GPa), dependingon

the specific alloy. For example, a 300-

μ

mthick complex boride

layerwas formedonNi

3

Al intermetallicmaterial in15minutes,

Fig. 1 —

Evolution of boriding units: (a) initial (1.75 in. diameter),

(b) intermediate (4 and 6 in. diameters), (c) pilot-scale (22 in. di-

ameter), and (d) large-scale (43 in. long

×

57 in. wide

×

54 in. deep)

production units.

(a) (b) (c)

(d)

Fig. 2 —

Industrial parts treated using ultrafast boriding:

(a) engine piston pin, (b) titanium textile guide, (c) superalloy

bearing part, (d) Inconel 718 ball valve, (e) agricultural knife

guard, (f) engine piston ring, and (g) engine tappet.

(a) (b) (c) (d)

(e) (f) (g)